Pathophysiology of peste des petits ruminants in sheep (Dorper & Kajli) and goats (Boer & Beetal)

Accepted Manuscript Pathophysiology of peste des petits ruminants in sheep (Dorper & Kajli) and goats (Boer & Beetal) Ahrar Khan, M. Kashif Saleemi, Farah Ali, Muhammad Abubakar, Riaz Hussain, Rao Zahid Abbas, Imtiaz Ahmad Khan PII:

S0882-4010(18)30008-1

DOI:

10.1016/j.micpath.2018.02.009

Reference:

YMPAT 2775

To appear in:

Microbial Pathogenesis

Received Date: 2 January 2018 Revised Date:

4 February 2018

Accepted Date: 6 February 2018

Please cite this article as: Khan A, Saleemi MK, Ali F, Abubakar M, Hussain R, Abbas RZ, Khan IA, Pathophysiology of peste des petits ruminants in sheep (Dorper & Kajli) and goats (Boer & Beetal), Microbial Pathogenesis (2018), doi: 10.1016/j.micpath.2018.02.009. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

ACCEPTED MANUSCRIPT 1

Pathophysiology of Peste Des Petits Ruminants in Sheep (Dorper & Kajli) and

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Goats (Boer & Beetal)

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Ahrar Khan1*, M. Kashif Saleemi1, Farah Ali2, Muhammad Abubakar3, Riaz

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Hussain2, Rao Zahid Abbas1 and Imtiaz Ahmad Khan4

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Pakistan.

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Faculty of Veterinary Science, University of Agriculture, Faisalabad-38000,

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Bahawalpur- 63100, Pakistan.

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University College of Veterinary and Animal Sciences, The Islamia University of

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National Veterinary Laboratory, Islamabad, Pakistan

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Department of Pathobiology, PMAS-Arid Agriculture University, Rawalpindi-

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46000, Pakistan

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17 Corresponding Author:

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Ahrar Khan (

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Department of Pathology,

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Faculty of Veterinary Science,

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University of Agriculture,

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Faisalabad-38000, Pakistan;

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[email protected]; [email protected]

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Phone: +92 333 651 7844

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https://orcid.org/0000-0001-5492-426)

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Page 1 of 23

ACCEPTED MANUSCRIPT Abstract

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Peste des petits ruminants (PPR), an economically important viral transboundary

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disease of small ruminants is not only prevalent in Pakistan but also in other countries

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where people rely on agriculture and animal products. The present study was aimed at

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describing the pathology and antigen localization in natural PPR infections in local

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(Kajli sheep; Beetal goats) as well as imported small ruminant breeds (Dorper sheep;

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Australian Boer goat). Morbidity and mortality rates were significantly (P < 0.001)

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higher in indigenous Kajli sheep (75.37 and 32.80 %) and Beetal goats (81.10 and

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37.24 %) as compared to Dorper sheep (6.99 and 1.48 %) and Australian Boer goat

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(5.01 and 2.23 %). Affected animals exhibited high fever, severe diarrhea, abdominal

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pain, respiratory distress and nodular lesions on lips and nostrils. Thick mucous

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discharge was oozing out from nostrils. On postmortem examination, lungs were

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congested and pneumonic, with nodular and cystic appearance and intestines were

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hemorrhagic with zebra stripping. Characteristic histopathological lesions of PPR

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were noted in intestines, lymphoid organs and lungs. In GI tract, stunting and blunting

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of villi, necrotic enteritis, and infiltration of mononuclear cells in duodenum, jejunum

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and ileum. Small intestines exhibited diffuse edema of the submucosa along with

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proliferation of fibrocytes, leading to thickened submucosa which has not been

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reported previously. Lymphoid organs showed partial to complete destruction of

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lymphoid follicles. Lesions of the respiratory tract included depictive of

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bronchopneumonia, severe congestion of trachea and apical lobe of lungs with

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deposition of fibrinous materials. Histopathological lesions of respiratory tract were

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severe and characteristic of broncho interstitial pneumonia, bronchopneumonia,

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interstitial pneumonia and fibrinous pneumonia. The alveoli were filled with

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edematous fluid mixed with fibrinous exudate, numerous alveolar macrophages,

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mononuclear cells along with thickened interalveolar septa and presence of

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intranuclear eosinophilic inclusions. One-Step RT-PCR using NP3 and NP4 primers

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confirmed a PPR virus of 352 bp size in spleen, lungs and mesenteric and brachial

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lymph node samples. It was concluded that morbidity and mortality due to PPR were

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significantly higher in indigenous breeds of sheep and goat as compared to imported

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sheep and goat breeds. PPR has rendered various lesions in GI and respiratory tract

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which are characteristic in nature for the diagnosis of the disease under field

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condition.

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Keywords: Peste des petits ruminants, sheep, goat, morbidity, mortality, gross and

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histopathological lesions of GI and respiratory tract

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1.

Introduction

66 The economy of Pakistan is agro-livestock based and role of livestock in agriculture

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sector is pivotal in rural socio-economic development [1-3]. Nearly eight million

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families in the country are involved in livestock raising. This sector is a source of

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income, and often the only source of income, for the rural and most marginal people,

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thus playing a key role in poverty alleviation [4,5]. Livestock sector is contributing

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approximately 58.6 % to the agriculture value added and 11.6 % to the overall GDP in

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Pakistan. Sheep and goats, being dual purpose animals with estimated population of

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70.3 and 29.8 million heads, respectively, are used for meat and to some extent for

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milk production [6].

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Sheep and goat farming in Pakistan is progressing rapidly and is contributing

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significantly to the national economy. However, its growth is being hampered by

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various diseases [7], including respiratory ailments like peste des petits ruminants

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[8,9]. Peste des petits ruminants (PPR) is reportable to the World Organization for

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Animal Health (OIE) and is an economically important disease in parts of Africa and

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some Asian countries. It is among transboundary diseases [10,11] and is not only

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present in Pakistan [12-15] but also in surrounding countries, including Afghanistan

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[16,17], India [18-21], Iran [22] and China [23,24]. This disease has also been

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reported from east African and Middle East countries and from most third world

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countries where people rely on agriculture and animal products [25,26].

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PPR is primarily a disease of sheep and goat but it has also been reported in

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Ethiopian camels, Indian buffalos [27], Saudian gazelles and deers [28] etc. Peste des

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petits ruminants, also known as goat plague and ovine rinderpest, affects sheep, goats

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and related species of small ruminants [29] and is highly contagious viral disease

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[30,31]. Morbillivirus, the causative agent, is closely related to rinderpest, measles

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and canine distemper virus [17,32]. The principal pathological findings of PPR are

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seen in the digestive and respiratory systems [33,34]. Morbidity and mortality could

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be 5-90 and 50-80 %, respectively [35,36].

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Vaccination is a strategy to control PPR and the vaccine is required at mass

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scale, however, losses can be curtailed through preventive measures for which Page 3 of 23

ACCEPTED MANUSCRIPT knowledge of pathology and pathogenesis of the disease is of vital. Studies of PPR

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usually revolve around sero-epidemiology [12,36,37] and rare efforts have been made

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to report its pathology. Most of the available information on the pathology of PPR has

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been based on results obtained following experimental infections [38] but none in

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Dorper or Kajli sheep and Boer or Beetal goats under field conditions. Data regarding

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pathological parameters from field cases are very important as these can better

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characterize the pathogenicity of the circulating virus. However, such data of PPR in

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Dorper/Kajli sheep and Boer/Beetal goats are lacking in the published literature. The

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severity of the disease varies with species, immunity and breed of the host [29]. The

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present study was aimed at describing the pathology and antigen localization in

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natural PPR infections in exotic sheep and goat breeds (Boer goat and Dorpar sheep)

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kept in close contact with local sheep (Kajli) and goat (Beetal) breeds.

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2.

Materials and methods

2.1.

Study Area and Environment

Lahore is the capital city of the Punjab province of Pakistan. It is the second most populous city in Pakistan and the 32nd most populous city in the world [39]. The

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city is located in the north-eastern end of the province, bordering with the Indian state

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of Punjab. Lahore has a semi-arid climate. Lying between 31°15′ - 31°45′ N and

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74°01′ - 74°39′ E, Lahore is bounded on the north and west by the Sheikhupura

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District, on the east by Wagah, and on the south by Kasur District. Study area was in

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suburban of Lahore towards Kasur District. Here, the hottest month of the year is

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June, with an average temperature of 40 °C (104.0 °F) and the coldest month is

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January at 14°C (56°F) with dense fog [1]. The monsoon season starts in late June,

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and the hot and humid month is July with heavy rainfalls, high humidity (81 %) and

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evening thunderstorms with the possibility of cloudbursts. This study was conducted

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in suburban of Lahore towards Kasur District during the mid of July.

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2.2.

Experimental animals and management

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At a private sheep and goat farm in suburban area of Lahore there were 2483

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animals including 1219 sheep and 1264 goats of two breeds each of sheep (Dorper

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All Animals were kept under similar managemental/housing conditions of shades with

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grassy grounds and free access to water and fodder. Animals of each breed were kept

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in individual barrens separated by wall/fence. Animals were offered seasonal green

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fodder such as Medicago sativa (alfalfa/Lucerne) supplemented with formulated

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concentrate. All the flock was allowed grazing once a day for 4-6 hours.

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Animals were vaccinated against pleuropneumonia, peste des petits ruminants

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and enterotoxaemia and dewormed twice a year. Before this outbreak, 40 Kajli sheep

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and 25 Beetal goats were purchased from the local market, quarantined for a week,

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vaccinated with PESTDOLL-S® Freeze dried live attenuated PPR Virus strain

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Nigeria 75/1 Vaccine (M/S Dollvet Veterinary Vaccine, Medicine and Biological

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Materials Production Inc, Eyyübiye/ŞANLIURFA, Turkey) and then allowed to join

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the herd. Animals were routinely inspected for any disease and suspected animals

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were separated from rest of the animals while. They were handled by the same

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workers of the farm.

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2.3.

Morality

During hot and humid month, i.e., July (average temperature 40 °C with high

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humidity (81 %), animals started becoming sick and mortality started. Morbidity and

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mortality reached to 48.77 % and 21.50 %, respectively (Table 1).

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2.4.

Gross and histopathological study

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Postmortem was conducted immediately after the death of the sheep and goat.

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As the lesions in sheep (Dorper and Kajli) and goats (Boer and Beetal) were the same,

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therefore, a common picture of lesions was developed. Gross lesions were recorded

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and classified based on severity as mild, moderate and severe [40]. Morbid organs

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were put into 10 % neutral buffered formalin to prevent postmortem changes and for

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fixation. The tissues were completely immersed in formalin solution and kept for 10

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days at room temperature for proper fixation. Then tissues were subjected to washing,

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dehydration in ascending concentrations of alcohol, clearing in xylene, impregnation

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and embedding in paraffin [41]. Tissues were further processed by paraffin sectioning

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and 4-5 µm thick sections were stained with hematoxylin and eosin staining technique

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[42-44]. Slides were examined for histopathological changes by two pathologists, and

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if any difference was found, a third pathologist was consulted for opinion.

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2.5.

Detection of PPRV nucleic acid through RT-PCR

167 For PCR analysis, tissue samples of liver, lung, spleen, mesenteric and

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bronchial lymph nodes were collected in sterilized zip bags, kept in ice pack

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containers and transported to the laboratories for further processing. Pooled tissues of

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each organ were macerated using PBS as 20 % (w/v) suspension and centrifuged at

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800 g for 10 minutes. The supernatant was collected in sterile Falcon tubes,

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gentamycin (500 µg/mL) was added and stored at -20°C. Freeze-dried live PPR

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vaccine from Veterinary Research Institute was used as the positive controls. From

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the homogenates, RNA was extracted from the tissue suspension and vaccine virus

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using RNeasy Kit (Qiagen, Germany) as recommended by the manufacturer

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homogenate [45].

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PPRV nucleic acid was determined through RT-PCR using Qiagen One-Step

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RT-PCR kit and the NP3 (5´-TCTCGGAAATCGCCTCACAGACTG -3´) and NP4

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(5´-CCTCCTCCTGGTCCTCCAGAATCT -3´) primers for the amplification of a

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352-bp fragment of the PPRV nucleoprotein gene [46]. Briefly, RNA (5 µL) was

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amplified in a reaction mix (45 µL) containing the following: 5× Qiagen buffer (10

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µL), dNTP mix (2 µL), of Q-solution (10 µL), and One-Step RT-PCR mix (2 µL),

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each primer at a final concentration (0.6 µM) and water. First reverse transcription of

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RNA was done by incubating at 50°C for 30 minutes, then the PCR started with an

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initial denaturation and activation of Taq polymerase at 95°C for 15 minutes. This

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was followed 40 cycles of amplification corresponding to 30 s at 94°C/30 s at 60°C/1

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min at 72°C and a final extension of 10 min at 72°C. Ten microliters of the amplified

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product was analyzed by electrophoresis in 1.5 % agarose gel and results were

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recorded through gel documentation system.

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2.6.

Differential Diagnosis with other Infectious Diseases

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It is worth mentioning that last case of rinderpest (cattle plague) in Pakistan

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was diagnosed in September 2000. In November 2000, vaccination against rinderpest

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was officially prohibited in Pakistan [47]. According to FAO and so many other

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workers [48], now this globe is free from rinderpest, moreover, this was the disease of

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large ruminants, however, small ruminants are being affected by PPR. PPR is being

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covered in the present study. Other infections like Foot and Mouth disease and Bluetongue disease can

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easily be differentiated from PPR based on clinical signs and symptoms. Foot and

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Mouth disease occurs in sheep and goats, however, severity of FMD in sheep and

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goats is variable, usually mild. Mouth lesions are often transient and blisters like and

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most characteristics is lameness due to foot lesions, these lesions are absent in PPR

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[49]. Bluetongue disease also effects sheep and goats. Affected animals show

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swelling of lips, muzzle, and oral mucosa, cyanosis of the tongue together with edema

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of the head region - sufficient to differentiate Bluetongue from PPR. Coronitis is also

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not feature of PPR [49]. On these basis, other infectious diseases were ruled out in the

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present study.

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2.7.

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Data collected were subjected to the Chi-square test, using the Minitab statistical software package [47]. The significance level was P < 0.05.

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3.

Results

3.1.

Morbidity, mortality and case fatality

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Out of 2483 sheep and goats, 48.77 % animals become morbid and 21.50 %

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died (Table 1). Overall, case fatality was 44.10 %. Morbidity and mortality were

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significantly (P < 0.001) higher in indigenous breeds viz. Kajli sheep (75.37 % and

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32.80 %) and Beetal goat (81.10 % and 37.24 %) as compared to exotic breeds, i.e.,

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Dorper sheep (6.99 % and 1.48 %) and Australian Boer goats (5.01 % and 2.23 %).

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However, case fatality did not vary among sheep and goat breeds (Table 1).

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3.2.

Clinical signs

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Affected animals showed elevated body temperature (40–41 °C) which

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remained so for 3-5 days. These were anorexic with dull coat, depressed and had dry

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muzzle. Affected animals also showed nasal discharge, lachrymation and catarrhal

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advanced stages. Morbid animals showed rales and abdominal breathing with

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respiratory distress. Severe watery or blood-stained diarrhea along with dehydration,

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emaciation and dyspnea and finally death were common features in affected animals.

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3.3.

Gross lesions of Gastro-intestinal tract

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With the onset of fever, gums became hyperemic, and erosive lesions developed on

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the oral mucosa; dental pad and tongue with excessive salivation along with necrotic

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stomatitis and erosions of visible mucous membranes.

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Erosive lesions on the hard palate, pharynx and upper third of the esophagus

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were observed. Main lesions in the gastro-intestinal tract were i) small streaks of

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hemorrhages and occasional erosions in the first portion of the duodenum and the

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terminal ileum, ii) hemorrhagic or necrotic enteritis with extensive necrosis (Fig. 1a)

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and sometimes severe ulceration of Peyer's patches, iii) congestion around the ileo-

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cecal valve, at the ceco-colic junction and in the rectum and iv) zebra stripes of

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congestion in the posterior part of colon (Fig. 1b). Congestion and zebra stripping

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were the lesions most frequently seen around the ileo-cecal valve, at the ceco-colic

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junction, rectum and colon. Congestion and enlargement of mesenteric lymph nodes,

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spleen and liver were also observed.

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3.4.

Histopathological lesions of Gastro-intestinal tract

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Characteristic histopathological lesions of PPR were noted in the intestines,

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lymphoid organs, liver and lungs. The intestines showed stunting and blunting of villi

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(Fig. 2a) with necrosis of tips of the villi, as well as sloughing of the villi (Fig. 2b).

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Lamina propria showed infiltration of mononuclear cells and a few neutrophils (Fig.

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2a). Small intestines also exhibited diffuse edema of the submucosa along with

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proliferation of fibrocytes, increasing thickness of submucosa (Fig. 2a & 2b).

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Degeneration and necrosis of glandular epithelial cells, particularly in the upper

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duodenum, jejunum and ileum, was also seen.

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Peyer’s patches showed partial or complete destruction of lymphoid follicles

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characterized by lympholysis and karyorrhexis. Goblet cells hyperplasia and

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The spleen showed marked depletion of lymphocytes of parafollicular areas in the

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white pulp, together with reticuloendothelial cell hyperplasia (Fig. 3a). Sinusoids

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were dilated and filled with macrophages and plasma cells, with a few neutrophils

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(Fig. 3b). Mesenteric and retropharyngeal lymph nodes and tonsils, showed lesions

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similar to those of the spleen. Liver showed multifocal areas of coagulative necrosis, vacuolation of

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hepatocytes along with dilatation of sinusoidal spaces and congestion. Many

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hepatocyte nuclei in such foci were pyknotic. The periportal area, exhibited

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infiltration of inflammatory cells, mostly neutrophils, and few mononuclear cells

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along with engorged blood vessels (Fig. 4a).

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3.5.

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Lesions in the Kidneys

Kidneys showed severe degenerative changes including degeneration, severe

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necrosis (Fig. 4b-d), vacuolation and desquamation of epithelium of renal tubules

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(Fig. 4b-c). Glomerular hemorrhages and hyaline cast in the tubular lumen were also

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recorded (Fig. 4b-c).

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Gross lesions of respiratory tract

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Lesions of the respiratory tract were suggestive of bronchopneumonia,

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however, main lesions were i) small erosions and petechiae on the nasal mucosa and

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larynx, ii) severe congestion of trachea (Fig. 5a) along with froth (Fig. 5b) and severe

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congestion of apical lobe of lungs (Fig. 6a-c), and iii) deposition of fibrinous material

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in the lungs (Fig. 6d).

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Histopathological lesions of respiratory tract

The histopathological lesions in the lungs were more severe and characteristic

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of broncho interstitial pneumonia. There was desquamation of bronchiolar

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epithelium with the presence of epithelial cell debris in the lumen of bronchioles

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which was indicative of bronchopneumonia (Fig. 7a). The alveoli showed edema tour

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fluid mixed with fibrinous exudate, alveolar macrophages, moderate to high numbers

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of neutrophils (Fig. 7b-d) along with thickened interalveolar septa (Fig. 7b), indicative

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of interstitial pneumonia. Infiltration of mononuclear cells in alveoli, along with

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hemorrhages, caused by the infiltration of erythrocytes, mononuclear cells and Page 9 of 23

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increased histiocyte proliferation was evident (Fig. 7). Fibrinous pneumonic lesions

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were accompanied by a serofibrinous exudate, with few macrophages and neutrophils

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in the alveolar lumina and presence of intranuclear eosinophilic inclusions (Fig. 8).

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3.8.

RT-PCR

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Gel electrophoresis for peste des petits ruminants one-step RT-PCR using NP3

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and NP4 primers showed a product of 352 bp size in spleen, lungs and mesenteric and

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brachial lymph node samples, while liver samples did not yield any results (Fig. 9).

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4.

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308 Discussion

PPR studies usually orbit sero-epidemiology [8,10,12,36,37,51] and rare

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efforts have been made to report its pathology. Pathology of PPR has been reported in

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different goat and sheep breeds following experimental infection [18,38,52] but none

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in Dorper or Kajli sheep and Boer or Beetal goats. For the diagnosis of PPR, clinical

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and post-mortem findings may be sufficient [53], histopathological observations and

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molecular diagnosis or isolation of virus described in this article will further

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strengthen the diagnosis [52]. According to Durrani et al. [54], there could be three

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methods to diagnose and monitor the distribution and prevalence of PPR i.e., case

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recording of PPR outbreaks, detection of the virus and serological detection of PPR

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specific antibodies. In the present study, first two methods, in addition to gross and

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histopathological lesions recording were followed.

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Overall morbidity and mortality in the present study was 48.77 % and 21.50

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%, respectively (Table 1). Morbidity and mortality were significantly higher (P <

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0.001) in indigenous breed of sheep (Kajli) and goat (Beetal) as compared to imported

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breeds (Dorper sheep; Boer goat). Dorper sheep and Boer goats are Australian breeds.

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PPR rendered low morbidity and mortality in animals of these imported breeds,

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probably due to the fact that PPR is exotic to Australia [55,56] and these breeds could

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be resistant to PPR virus [57]. Moreover, Dorper sheep have a high degree of

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disease resistance [58], this could be the other reason that morbidity and mortality was

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significantly lower (P < 0.001) in Dorper sheep as compared to local sheep breed

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(Kajli). In Pakistan, PPR appeared in 1991 for the first time in the Punjab province

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[59,60]. Despite vaccination, PPR spread to all parts of the country [9,12-15,54,61-

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63]. The high susceptibility of local sheep and goat breeds to PPR virus [64] could be

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due to ineffective quarantine, continuous spread of PPR virus in non-vaccinated

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population, unrestricted transportation, absence of passive and active surveillance

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[8,16]. In the present study, morbidity, mortality and case fatality rates did not vary

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significantly in sheep and goats (Table 1). Previous studies have reported significantly

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higher PPR infection rate in sheep as compared to goats [64]. Other studies reported

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higher prevalence of PPRV in goats than sheep [30,54,65-68]. The low prevalence of

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PPRV in sheep might be due to innate immune resistance [69]. The increased

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susceptibility of goats to PPRV than sheep can be due to less transmission of infection

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between these animals. Higher enzooticity of PPRV in goats than sheep could also be

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due to more adaptation and change in virulence of virus in goats which favors the

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spread of infection [30].

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Animals suffered with PPR showed high fever (40–41 °C) and serous nasal

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discharge in early stage of the disease, which became mucopurulent, dull coat,

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restless, depression, dry muzzle having lachrymation and catarrhal conjunctivitis in

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the present study. Moreover, morbid animals showed dyspnea, respiratory distress,

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severe watery or blood-stained diarrhea along with dehydration, emaciation and

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finally death. Various clinical signs such as anorexia, fever, depression, emaciation,

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stomatitis, occulo-nasal discharge, coughing, respiratory distress and death in

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naturally and experimentally infected goats have been reported earlier [70-72].

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The pathogenesis of PPRV is poorly understood, most of the information

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being based on comparison with related Morbilliviruses [73]. PPRV concentration is

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high in the exhaled air and body fluids i.e. saliva, oral and nasal discharges, urine,

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feces of the infected animals [74]. PPRV is primarily transmitted via the respiratory

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route among animals living in close proximity [75].

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Respiratory lesions in our study could be due to damage to respiratory mucosa

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(naso-pharyngeal/respiratory epithelium) [73,76]. It is reported that PPRV spreads to

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different other tissues of the body via regional lymphoid, then infects the lymphocytes

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and infection spreads throughout the body via both the lymphatic and vascular

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systems [71]. As the PPRV is both lympho- and epithelio-tropic [73], infection

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usually results in conjunctivitis, rhinotracheitis, ulcerative stomatitis, gastroenteritis

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and pneumonia which have been observed in the present study.

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At necropsy, main lesions were seen in the gastro-intestinal tract such as small

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and rectum along with severe congestion and enlargement of spleen and regional

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lymph nodes. These lesions might be due to extensive necrosis in lymphoid organs

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leading to inability of the animals to mount specific immune response to PPRV [76].

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In the present study, fragile liver, enlarged lymph nodes, severe enteritis along with

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streaks of hemorrhages ‘zebra stripes’, and enlargement and petechial hemorrhages in

373

the spleen were observed which have also been reported previously [18,19,29].

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Different pulmonary lesions observed in the present study including small

375

erosions on the nasal mucosa and larynx, congestion, petechiae, hemorrhages and

376

frothy exudates in the trachea, red hepatization, raised patches of emphysema in the

377

lungs, severe congestion of apical lobe of lungs and presence of fibrinous exudate in

378

the lungs have been reported in PPR infected sheep, goats [18] and camels [77].

SC

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At histopathological level, main lesions in the intestine such as stunting and

380

blunting of villi along with necrosis and sloughing of the villi could be due to

381

cytopathogenicity of PPRV, leading to necrosis/apoptosis. Squamous epithelial

382

syncytia are also observed in digestive tract epithelium following PPR infection

383

[73,74]. In the present study, small intestine also exhibited diffuse edema of the

384

submucosa along with proliferation of fibrocytes, leading to thickened submucosa

385

which has not been reported in the published literature as far as our knowledge is

386

concerned.

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In the present study, Peyer’s patches, spleen and lymph nodes in PPR affected

388

animals showed lympholysis, necrotic changes and depletion of lymphoid cells along

389

with hyperplasia of reticuloendothelial cells. Like Morbillivirus, PPRV has great

390

affinity to lymphoid cells [29,72], causing damage to the lymphoid organs [72,74,78].

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Histologically, liver of sheep died of PPR in the present study showed

392

multifocal necrotic areas in the present study which have been reported in the

393

published literature [49,79]. Moreover, coagulative necrosis, multifocal vacuolation of

394

hepatocytes, perivascular mononuclear cellular infiltration, especially in portal areas,

395

and macrophage aggregations within parenchyma have been reported [72].

396

Histological analysis of liver tissues in the present study showed engorged blood

397

vessels, dilation of sinusoidal spaces, hemorrhages and infiltration of neutrophils and

398

mononuclear cells, particularly in periportal areas [18].

399

Kidneys also showed degenerative changes in infected animals in the present

400

study. Severe necrosis, vacuolation, degeneration and desquamation of tubular Page 12 of 23

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epithelium, glomerular hemorrhages and hyaline tubular cast in the tubular lumen

402

have been reported in kidneys of infected goats [18]. Kidneys revealed congestion in

403

glomeruli and cortical blood vessels [70]. As the PPRV is primarily transmitted via the respiratory route [75], this tract is

405

severely affected. In our study, lesions like broncho interstitial pneumonia,

406

bronchopneumonia, extensive alveolar edema mixed with fibrinous exudate,

407

interstitial pneumonia characterized by thickened interalveolar septa and fibrinous

408

pneumonia were recorded in affected animals. Presence of intranuclear eosinophilic

409

inclusions in alveolar macrophages was another important feature noted in affected

410

animals, as reported previously [29,49,72]. Available published literature shows that

411

upon exposure to virulent PPRV, susceptible animals usually develop acute

412

pulmonary congestion and edema, leading to bronchopneumonia and even diffused

413

pneumonia, then succumb to death [19,73]. In the same sequence the events in the

414

respiratory tract of died animals took place in the present study.

415 416

Conflict of interest

417

Authors have stated no competing interests.

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418

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T.U. Obi, M.O. Ojo, O.A. Durojaiye, O.B. Kasali, S. Akparie, D.B. Opasina,

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Peste des petits ruminants in goats in Nigeria: clinical, microbiological and

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pathological features, Zentralbl Veterinarmed B. 30 (1983) 751–761.

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Table 1: Morbidity, mortality and case fatality in sheep and goats due to peste des

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petits ruminants Breeds

Total

*Morbidity

Animals

N

**Mortality

%

N

%

***Case Fatality (%)

Sheep breeds 472

33

6.99

7

Kajli

747

563

75.37

245

Dorper vs Kajli sheep

P Value = 0.001

P Value = 0.001

P Value = 0.083

5.01

Beetal

725

588

81.10

12

2.23

44.44

270

37.24

45.92

χ2 Value = 148.116

χ2 Value = 0.008

P Value = 0.001

P Value = 0.001

P Value = 0.927

Sheep

1219

596

Goats

1264

615

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χ2 Value = 287.594

48.89

252

20.67

42.28

48.65

282

22.31

45.85

χ2 Value = 0.005

χ2 Value = 0.637

χ2 Value = 0.608

P Value = 0.945

P Value = 0.425

P Value = 0.436

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670

SC

27

2483

43.52

χ2 Value = 3.000

539

Total/Overall

32.80

χ2 Value = 122.853

Boer

Sheep vs Goats

21.21

χ2 Value = 219.485

Goat breeds

Boer vs Beetal goats

1.48

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Dorper

1211

48.77

534

21.50

44.10

Data analysis by Chi-square test and df in each case was 1.

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EP

Number of animals became sick

*Morbidity % =

Total number of animals at risk

X 100

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Number of animals died

**Mortality % =

***Case Fatality (%) = 672

Total number of animals at risk

X 100

Number of animals died Number of animals became sick

X 100

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Captions of Figures

674 675

Fig. 1:

Photographs of intestines of a) a sheep and b) a goat died of peste des petits

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ruminants showing streaks of hemorrhages (zebra stripping) and blood clots

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(arrows). Fig. 2:

Photomicrographs of intestines of a goat (a and b) died of peste des petits

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ruminants, showing stunting and blunting of villi (arrows) with necrosis of

680

tips of the villi, as well as sloughing of the villi (arrow head). There is

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infiltration of the lamina propria with mononuclear cells and a few

682

neutrophil leukocytes (asterisk) along with diffuse edema of the submucosa

683

and proliferation of fibrocytes, forming the submucosa much thickened

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(double-head arrow). H and E Stain. X 100. Fig. 3:

Photomicrographs of spleen of a sheep (a and b) died of peste des petits

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SC

679

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ruminants, showing marked depletion of lymphocytes in the white pulp,

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together with reticuloendothelial cell hyperplasia (arrow heads) and

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congestion (arrow). Dilated sinusoidal spaces are filled with macrophages

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and plasma cells, with a few neutrophils. H and E Stain. X 100. Fig. 4:

Photomicrograph of liver (a) of a goat died of peste des petits ruminants,

TE D

690

showing congestion (arrow head), cellular infiltration (arrows) and many

692

hepatocytes have under gone degeneration. b-d) kidneys of sheep and goat

693

died of peste des petits ruminants showing renal tubular necrosis (arrows),

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detachment of tubular epithelium from the basement membrane and pooled

695

in the lumen (arrow heads) and filling of renal tubules with proteinaceous

696

material and casts (asterisks). H and E Stain. a) X 40; b & d) X 200 and c)

698 699 700

AC C

697

EP

691

X400.

Fig. 5:

Photograph of trachea of a sheep died of peste des petits ruminants, showing a) severe congestion and b) severe congestion with froth.

Fig. 6:

Photographs of lungs of a goat died of peste des petits ruminants showing

701

severe congestion of apical lobe of the lungs (a-c: arrows) and deposition of

702

fibrinous materials (d: arrow heads).

703

Fig. 7:

Photomicrograph of lungs of a sheep died of peste des petits ruminants

704

showing a) alveoli filled with serofibrinous edema fluid mixed with

705

fibrinous exudate (asterisks), numerous alveolar macrophages and moderate

706

numbers of neutrophil leukocytes in bronchioles (arrow) and in alveoli; b) Page 22 of 23

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thickened interalveolar septa (arrows) and extensive infiltration of

708

mononuclear cells in alveoli (arrow heads); c & d) characteristic interstitial

709

pneumonia with extensive infiltration of erythrocytes, mononuclear cells and

710

increased histiocyte proliferation. H and E Stain. a-c) X 100 and d) X 400.

711

Fig. 8:

Photomicrographs of lungs of a goat died of peste des petits ruminants showing lesions of bronchopneumonia. a-b) alveoli filled with serofibrinous

713

edema fluid mixed with fibrinous exudate (asterisks), congestion (arrows),

714

numerous alveolar macrophages and moderate numbers of neutrophil

715

leukocytes in alveoli; and intranuclear eosinophilic inclusions in alveolar

716

macrophages (arrows). H and E Stain. X400. Fig. 9:

SC

717

RI PT

712

Photograph of Gel electrophoresis for peste des petits ruminants one-step RT-PCR using NP3 and NP4 primers (product size = 352 bp). Lane 1 =

719

Ladder (bp); Lane 2 = Spleen sample; Lane 3 = Negative control; Lane 4 =

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Lungs sample; Lane 5 = Mesenteric lymph node sample; Lane 6 = Brachial

721

lymph node sample; Lane 7 = Liver sample and Lane 8 = Positive control.

M AN U

718

722 723

AC C

EP

TE D

724

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Highlights of the manuscript Pathophysiology of Peste Des Petits Ruminants in Sheep (Dorper & Kajli) and Goats (Boer & Beetal) •

Peste des petits ruminants was studied in local (Kajli sheep; Beetal goats) as well as

•

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imported small ruminant breeds (Dorper sheep; Australian Boer goat).

Morbidity and mortality rates were significantly higher in indigenous Kajli sheep and Beetal goats as compared to Dorper sheep and Australian Boer goat.

•

On postmortem examination, lungs were congested and pneumonic, with nodular and

•

SC

cystic appearance and intestines were hemorrhagic with zebra stripping.

Histopathological lesions of respiratory tract were severe and characteristic of broncho

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interstitial pneumonia, bronchopneumonia, interstitial pneumonia and fibrinous pneumonia.

One-Step RT-PCR using NP3 and NP4 primers confirmed a PPR virus of 352 bp size in

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various organs.

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•