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The amino acid composition of elastin in its soluble and insoluble state
Vol. 33, No. 2, 1968
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
THEAMINO ACID COMPOSITION OF ELASTIN IN ITS SOLUBLEAND INSOLUBLESTATE* Division
by J.A. Petruska and L.B. Sandbergf* of Biology, California Institute of Technology
Received September 3, 1968 Introduction The protein
elastin
is highly
insoluble in normal animals, being depos-
ited in a cross-linked
aggregated state (8).
has yet to be isolated
from normal elastic
Whenelastic
tissues,
ligament are autoclaved,
such as aorta, the elastin
Subsequent extraction
(5). elastin
Its soluble noncross-linked tissues.
nasal and ear cartilage,
is left
leads to somepurification
that pure elastin
amounts of other proteins may remain firmly to the elastin;
in particular,
tic
is ever obtained,
ground substance protein and collagen,
fraction
obtained by neutral-salt
but very little,
In animals raised on copper-deficient soluble protein
fraction
noncross-linked
form (13).
linked, of which
tissues (2,4), extraction
tissues from normal animals is mainly ground substance protein
collagen is also in this fraction,
of the Small
bound, perhaps covalently
there are considerable amounts in the elastic The soluble protein
and nuchal
behind as an insoluble residue
with hot alkali
(S), but it is doubtful
form
diets,
may contain substantial
of elas(4).
Some
if any, elastin, however, it appears that the amounts of elastin
in the
The amino acid compositions reported for soluble and insoluble elastictissue fractions
in normal and copper-deficient
animals are examined here.
making somereasonable assumptions about the protein to extrapolate
to a composition for pure elastin
By
components, we are able
in its
soluble and insoluble
states. *Supported by Public Health Service Grant GM06965. **Established Investigator of the American Heart Association, Present Address: Department of Surgery, University of Utah, Salt Lake City, Utah.
222
Vol. 33, No. 2, 1968
Sources
of
8lOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Data
The amino acid compositions examined pertain tic
tissue fractions.
and nasal cartilage
The bovine tissues are nuchal ligament (2 , 4 , 5#9#ll), (5,9),
and aorta (5) of normal cattle;
are aortas of normal and copper-deficient are obtained by neutral-salt autoclaving
(2,s).
to bovine and porcine elas-
extraction
swine (13). (4,9,13);
Although data are available
8
7
65432
CONTENT
the porcine tissues
The soluble fractions
the insoluble
fractions
by
for insoluble fractions
8
OF GLY (RES
ear
7
654321
E
PER 1000)
Fig. 1. Amino acid plots against gly, before correction for collagen (dotted lines and open dots), and after correction for collagen (solid lines and closed dots), for normal bovine elastic tissue fractions. 1,2,3, and 4 are insoluble fractions from nuchal ligament of g-year old cow (ll), l-year old cow (11), adult cattle of unspecified age (S), and term-foetal calf (ll), respectively, 5 and 6 are insoluble fractions from aorta and ear cartilage, respectively, of adult cattle of unspecified age (5). 7 is a soluble fraction from autoclaved bovine nuchal ligament (4); 8, the ground substance protein isolated from the soluble fraction of bovine nasal cartilage (9). The straight lines are fitted to the points by the least-squares method.
223
BIOCHEMICAL
Vol. 33, No. 2, 1968
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
cleansed with hot alkali
(1,5),
these data are not used because the alkali
treatment is destructive
to someof the amino acids, particularly
arginine,
Assumptions Two assumptions are made about the protein sues.
First,
components in the elastic
tis-
we assumethat only three components are present in significant
amounts; namely, elastin,
ground substance protein,
and collagen,
suppose that collagen is the only component containing The amino acid contributions of hypro, are calculated
from collagen,
Second, we
hydroxyproline
(hypro),
corresponding to the content
using the composition of purified
32
collagen from calf
I E
50 0 PRO
50 0
a
0
'
'
'
'
'
'1)
CONTENT
1
OF GLY (RES.
PER 1000)
Fig. 2. Amino acid plots against gly, before correction for collagen (dotted lines and open dots), and after correction for collagen (solid lines and closed 1 is the insoluble fraction; 2 and dots), for normal porcine aortic fractions. of the soluble fraction left 3 are the residue and supernatant, respectively, The straight lines were standing in the cold (13), as a step in purification. fitted by least squares.
224
Vol. 33, No. 2, 1968
(6)
BIOCfiEMICAL
and pig (3) skins,
AND BfOfWYSICAL RESEARCH COMMUNICATIONS
In correcting
for collagen, we subtract
these contri-
butions from the observed amino acid contents in the fractions, before and after total
correction
The contents
for collagen are expressed in residues per 1000
amino acid residues and plotted
as described below,
The content of one of the amino acids showing a large net change, specifically
gly,
ala, or val,
is plotted
the ordinate,
is then plotted
amino acids.
When the data for all
Against this,
along
the corresponding content for each of the other the fractions
are so plotted,
the points
/'
200
. / /'I
150
100 l ’ 50;i'^ ’
along the abscissa.
/
,
HO
i
HIS
/ I
I
0 50 0 50 0 150 IOQ 50 0 200
CONTENT
OF GLY (RES.
PER 1000)
Fig. 3. Amino acid plots against gly, before correction for collagen (dotted lines and open dots), and after correction for collagen (solid lines and closed dots), for Cu-deficient porcine aortic fractions. 1 and 2 are residues from soluble fractions coacervated at room temperature (13); 3 and 4 are supernatant and residue, respectively, from soluble fraction left standing in the cold (13) 5 and 6 are residue and supernatant, respectively, from normal aortic soluble fraction left standing in the cold (same as 2 and 3, respectively, in Fig, 2). The straight lines are the least-squares fit.
225
Vol. 33, No. 2, 1968
BIOCHEMICAL
AND BIOPHYSIC~L RESEARCH COMMUNICATIONS
for each amino acid should lie on a straight substance protein
and ground
This is the line connecting pure elastin
are present,
pure ground substance protein,
and
If collagen is present in the amounts calcu-
lated from hypro, there should be a better rection
line if only elastin
fit
to a straight
line after
cor-
for collagen,
Results The results
are very similar
Here we described the results rection
for collagen,
whether one plots against gly,
of plotting
line indicates
against gly before and after
To each set of points plotted,
by least squares (Figs. 1,2,3).
of the standard deviation
a straight
The standard deviation
the goodness of fit
ala, or val.
correction
line is fitted
of the points from the
in each case (Table I),
is smaller after
cor-
The average value
for collagen than before
(Table I). Table I Average Value of the Standard Deviation Between the Points and the Lines For the Sets of Plots in Figs, 1 to 3 Average Standard Deviation in Residues per 1000 Residues After Correction Before Correction For Collagen Figure For Collagen 1 2 3
After
4.4 2.3 4.7
correction
axis at the samepoint, lrE1l
for collagen,
Moving vertically
several of the lines intersect
“E” (Figs, 1,2,3).
corresponds to pure elastin
sent.
3.9 2.0 3.1
The simplest interpretation
is that
in which these amino acids are completely ab-
along the dashed line at “E,” we can read off
corresponding contents of other amino acids from the lines. arrive
the gly
at the compositions for pure elastin
the
In this manner we
as shown in Table II.
Discussion The computed compositions for soluble elastin and insoluble
elastin
in normal swine are identical
226
in copper-deficient within
swine
the errors of amino
Vol. 33, No. 2, 1968
acid analysis,
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
except for the content of lysine.
bers noted between these two elastins
(Table II)
sine lost during the formation of cross-links, in the tables.
For the soluble elastin,
The small difference can be attributed
in num-
to the ly-
These have not been included
there are 46 residues of lysine per
Table II Amino Acid Contents Assigned to Pure Elastin Amino Acid
Amino Acid Residues per 1000 Residues Normal Bovine Normal Porcine Cu-Deficrent Porcine Insoluble Elastin Insoluble Elastin Soluble Elastin 334 236 127 154 27 67 34 0 0 0 5.7 9.0 0 0 0 0 6 5.9
GUY Ala Pro Val Ilu Leu Phe Met CYS Ser
Thr Tyr TV His Arg Ls + Gi::
328 250 109 147 19 57 36 1.1 0 7.2 13 20 0 0 1.3 2.1 0 10
320 236 106 138 21 53 32 0 0 5.3 13 18 0 0 0.4 % 12
Each value is the average of the values determined from the plots xnst gly, ala, and val after correction for collagen, The determination is made at the point where the line for Asx intercepts the ordinate (the point labelled “Eft in Figs. l-3). The content of lysine is underlined to emphasize its much larger value in copper-deficient porcine elastin. Note :
1000 residues of amino acid.
With the insoluble material,
tent has dropped to two residues per 1000 residues.
the lysine con-
This difference
Iysine content is in part due to the production of the cross-linking stances desmosine, isodesmosine, and lysinonorleucine.
in sub-
However, these
known derivatives
of lysine,
for approximately
one-half of the lysine present in the insoluble material,
Recent reports
which occur in insoluble elastin,
(7,10) have indicated
account only
the presence of aldehydes in elastin
derived from the enzymatic conversion of lysine to alpha-amino adipic-
227
Vol. 33, No. 2, 1968
semialdehyde.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
This aldehyde content of elastin
seventh of the total would therefore
accounts for about one-
lysine in the noncross-linked
soluble material,
seem that the remaining lysine residues are either
during the conversion of soluble elastin
to the insoluble fiber
cess of enzymatic peptide cleavage, or more likely, cross-linking
It lost
by somepro-
they are converted to
substances which have not as yet been identified.
has already been presented in favor of the latter
Someevidence
argument (12).
The good agreement between the two computed compositions for soluble and insoluble porcine elastin like protein ally,
(Table II),
reported by Smith, -et al,
the elastin
precursor
substantiates
that the soluble elastin-
(13) is closely related
(tropoelastin).
Further,
it can be said that the
coacervated product reported by these workers is a fairly impurities
to, if not actu-
pure protein;
the
being collagen and ground substance proteins present in not greater
than 15%concentration, Minimum molecular size of both bovine and porcine soluble elastin indicated
by amino acid composition is predicted
approximately
30,000 molecular polypeptide
as
to be about 350 residues or
weight.
References
1. 2.
43: 5. 6. 7. 8. 9.
10. 11. 12. 13.
Cleary, E.G., L.B. Sandberg, and D.S. Jackson, Biochemistry and Physiology of Connective Tissue, P. Comte, editor, Societe Ormeco et Imprimerie du Sud-Est Lyons, France, 1966, p, 167. Cleary, E.G., L.B. Sandberg, and D.S. Jackson, J, Cell Biol., z (1967) 469. Eastoe, J.E., Biochem. J., 61 (1955) 589. and V. Moret, J, Atheroscler. Res., 2 Gotte, L., Serafini-Fracas&ii, (1963) 244, Gotte, L., P. Stern, D.F. Elsden, and S.M. Partridge, Biochem, J., g (1963) 344. Heidrich, H.G. and L.K. Wynston, 2. Physiol. Chem., 342 (1965) 342, Miller, E.J. and H.M. Fullmer, J. Exp, Med., 123 (19m 1097. Partridge, Fed. Proc., 25 (1966) 1023 Partridge, S.M., H.F. DGis, and G.S. Adair, Biochem. J., 79 (1961) 15. Science, 161 v968) 475. Pinnell, S.R., G.R. Martin, and E.J. Miller, Sandberg, L.B., Ph.D. Thesis, Grad, Div. of the Univ. of Ore. Med. School, 1966. Sandberg, L.B. and E.G. Cleary, Biochim. Biophys. Acta, 154 (1968) 411. N. Weissman, and W.H. Carnes, Biochem, BiopF. Res. COPIOUS., Smith, D.W., 31 (1968) 309. 228
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
THEAMINO ACID COMPOSITION OF ELASTIN IN ITS SOLUBLEAND INSOLUBLESTATE* Division
by J.A. Petruska and L.B. Sandbergf* of Biology, California Institute of Technology
Received September 3, 1968 Introduction The protein
elastin
is highly
insoluble in normal animals, being depos-
ited in a cross-linked
aggregated state (8).
has yet to be isolated
from normal elastic
Whenelastic
tissues,
ligament are autoclaved,
such as aorta, the elastin
Subsequent extraction
(5). elastin
Its soluble noncross-linked tissues.
nasal and ear cartilage,
is left
leads to somepurification
that pure elastin
amounts of other proteins may remain firmly to the elastin;
in particular,
tic
is ever obtained,
ground substance protein and collagen,
fraction
obtained by neutral-salt
but very little,
In animals raised on copper-deficient soluble protein
fraction
noncross-linked
form (13).
linked, of which
tissues (2,4), extraction
tissues from normal animals is mainly ground substance protein
collagen is also in this fraction,
of the Small
bound, perhaps covalently
there are considerable amounts in the elastic The soluble protein
and nuchal
behind as an insoluble residue
with hot alkali
(S), but it is doubtful
form
diets,
may contain substantial
of elas(4).
Some
if any, elastin, however, it appears that the amounts of elastin
in the
The amino acid compositions reported for soluble and insoluble elastictissue fractions
in normal and copper-deficient
animals are examined here.
making somereasonable assumptions about the protein to extrapolate
to a composition for pure elastin
By
components, we are able
in its
soluble and insoluble
states. *Supported by Public Health Service Grant GM06965. **Established Investigator of the American Heart Association, Present Address: Department of Surgery, University of Utah, Salt Lake City, Utah.
222
Vol. 33, No. 2, 1968
Sources
of
8lOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Data
The amino acid compositions examined pertain tic
tissue fractions.
and nasal cartilage
The bovine tissues are nuchal ligament (2 , 4 , 5#9#ll), (5,9),
and aorta (5) of normal cattle;
are aortas of normal and copper-deficient are obtained by neutral-salt autoclaving
(2,s).
to bovine and porcine elas-
extraction
swine (13). (4,9,13);
Although data are available
8
7
65432
CONTENT
the porcine tissues
The soluble fractions
the insoluble
fractions
by
for insoluble fractions
8
OF GLY (RES
ear
7
654321
E
PER 1000)
Fig. 1. Amino acid plots against gly, before correction for collagen (dotted lines and open dots), and after correction for collagen (solid lines and closed dots), for normal bovine elastic tissue fractions. 1,2,3, and 4 are insoluble fractions from nuchal ligament of g-year old cow (ll), l-year old cow (11), adult cattle of unspecified age (S), and term-foetal calf (ll), respectively, 5 and 6 are insoluble fractions from aorta and ear cartilage, respectively, of adult cattle of unspecified age (5). 7 is a soluble fraction from autoclaved bovine nuchal ligament (4); 8, the ground substance protein isolated from the soluble fraction of bovine nasal cartilage (9). The straight lines are fitted to the points by the least-squares method.
223
BIOCHEMICAL
Vol. 33, No. 2, 1968
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
cleansed with hot alkali
(1,5),
these data are not used because the alkali
treatment is destructive
to someof the amino acids, particularly
arginine,
Assumptions Two assumptions are made about the protein sues.
First,
components in the elastic
tis-
we assumethat only three components are present in significant
amounts; namely, elastin,
ground substance protein,
and collagen,
suppose that collagen is the only component containing The amino acid contributions of hypro, are calculated
from collagen,
Second, we
hydroxyproline
(hypro),
corresponding to the content
using the composition of purified
32
collagen from calf
I E
50 0 PRO
50 0
a
0
'
'
'
'
'
'1)
CONTENT
1
OF GLY (RES.
PER 1000)
Fig. 2. Amino acid plots against gly, before correction for collagen (dotted lines and open dots), and after correction for collagen (solid lines and closed 1 is the insoluble fraction; 2 and dots), for normal porcine aortic fractions. of the soluble fraction left 3 are the residue and supernatant, respectively, The straight lines were standing in the cold (13), as a step in purification. fitted by least squares.
224
Vol. 33, No. 2, 1968
(6)
BIOCfiEMICAL
and pig (3) skins,
AND BfOfWYSICAL RESEARCH COMMUNICATIONS
In correcting
for collagen, we subtract
these contri-
butions from the observed amino acid contents in the fractions, before and after total
correction
The contents
for collagen are expressed in residues per 1000
amino acid residues and plotted
as described below,
The content of one of the amino acids showing a large net change, specifically
gly,
ala, or val,
is plotted
the ordinate,
is then plotted
amino acids.
When the data for all
Against this,
along
the corresponding content for each of the other the fractions
are so plotted,
the points
/'
200
. / /'I
150
100 l ’ 50;i'^ ’
along the abscissa.
/
,
HO
i
HIS
/ I
I
0 50 0 50 0 150 IOQ 50 0 200
CONTENT
OF GLY (RES.
PER 1000)
Fig. 3. Amino acid plots against gly, before correction for collagen (dotted lines and open dots), and after correction for collagen (solid lines and closed dots), for Cu-deficient porcine aortic fractions. 1 and 2 are residues from soluble fractions coacervated at room temperature (13); 3 and 4 are supernatant and residue, respectively, from soluble fraction left standing in the cold (13) 5 and 6 are residue and supernatant, respectively, from normal aortic soluble fraction left standing in the cold (same as 2 and 3, respectively, in Fig, 2). The straight lines are the least-squares fit.
225
Vol. 33, No. 2, 1968
BIOCHEMICAL
AND BIOPHYSIC~L RESEARCH COMMUNICATIONS
for each amino acid should lie on a straight substance protein
and ground
This is the line connecting pure elastin
are present,
pure ground substance protein,
and
If collagen is present in the amounts calcu-
lated from hypro, there should be a better rection
line if only elastin
fit
to a straight
line after
cor-
for collagen,
Results The results
are very similar
Here we described the results rection
for collagen,
whether one plots against gly,
of plotting
line indicates
against gly before and after
To each set of points plotted,
by least squares (Figs. 1,2,3).
of the standard deviation
a straight
The standard deviation
the goodness of fit
ala, or val.
correction
line is fitted
of the points from the
in each case (Table I),
is smaller after
cor-
The average value
for collagen than before
(Table I). Table I Average Value of the Standard Deviation Between the Points and the Lines For the Sets of Plots in Figs, 1 to 3 Average Standard Deviation in Residues per 1000 Residues After Correction Before Correction For Collagen Figure For Collagen 1 2 3
After
4.4 2.3 4.7
correction
axis at the samepoint, lrE1l
for collagen,
Moving vertically
several of the lines intersect
“E” (Figs, 1,2,3).
corresponds to pure elastin
sent.
3.9 2.0 3.1
The simplest interpretation
is that
in which these amino acids are completely ab-
along the dashed line at “E,” we can read off
corresponding contents of other amino acids from the lines. arrive
the gly
at the compositions for pure elastin
the
In this manner we
as shown in Table II.
Discussion The computed compositions for soluble elastin and insoluble
elastin
in normal swine are identical
226
in copper-deficient within
swine
the errors of amino
Vol. 33, No. 2, 1968
acid analysis,
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
except for the content of lysine.
bers noted between these two elastins
(Table II)
sine lost during the formation of cross-links, in the tables.
For the soluble elastin,
The small difference can be attributed
in num-
to the ly-
These have not been included
there are 46 residues of lysine per
Table II Amino Acid Contents Assigned to Pure Elastin Amino Acid
Amino Acid Residues per 1000 Residues Normal Bovine Normal Porcine Cu-Deficrent Porcine Insoluble Elastin Insoluble Elastin Soluble Elastin 334 236 127 154 27 67 34 0 0 0 5.7 9.0 0 0 0 0 6 5.9
GUY Ala Pro Val Ilu Leu Phe Met CYS Ser
Thr Tyr TV His Arg Ls + Gi::
328 250 109 147 19 57 36 1.1 0 7.2 13 20 0 0 1.3 2.1 0 10
320 236 106 138 21 53 32 0 0 5.3 13 18 0 0 0.4 % 12
Each value is the average of the values determined from the plots xnst gly, ala, and val after correction for collagen, The determination is made at the point where the line for Asx intercepts the ordinate (the point labelled “Eft in Figs. l-3). The content of lysine is underlined to emphasize its much larger value in copper-deficient porcine elastin. Note :
1000 residues of amino acid.
With the insoluble material,
tent has dropped to two residues per 1000 residues.
the lysine con-
This difference
Iysine content is in part due to the production of the cross-linking stances desmosine, isodesmosine, and lysinonorleucine.
in sub-
However, these
known derivatives
of lysine,
for approximately
one-half of the lysine present in the insoluble material,
Recent reports
which occur in insoluble elastin,
(7,10) have indicated
account only
the presence of aldehydes in elastin
derived from the enzymatic conversion of lysine to alpha-amino adipic-
227
Vol. 33, No. 2, 1968
semialdehyde.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
This aldehyde content of elastin
seventh of the total would therefore
accounts for about one-
lysine in the noncross-linked
soluble material,
seem that the remaining lysine residues are either
during the conversion of soluble elastin
to the insoluble fiber
cess of enzymatic peptide cleavage, or more likely, cross-linking
It lost
by somepro-
they are converted to
substances which have not as yet been identified.
has already been presented in favor of the latter
Someevidence
argument (12).
The good agreement between the two computed compositions for soluble and insoluble porcine elastin like protein ally,
(Table II),
reported by Smith, -et al,
the elastin
precursor
substantiates
that the soluble elastin-
(13) is closely related
(tropoelastin).
Further,
it can be said that the
coacervated product reported by these workers is a fairly impurities
to, if not actu-
pure protein;
the
being collagen and ground substance proteins present in not greater
than 15%concentration, Minimum molecular size of both bovine and porcine soluble elastin indicated
by amino acid composition is predicted
approximately
30,000 molecular polypeptide
as
to be about 350 residues or
weight.
References
1. 2.
43: 5. 6. 7. 8. 9.
10. 11. 12. 13.
Cleary, E.G., L.B. Sandberg, and D.S. Jackson, Biochemistry and Physiology of Connective Tissue, P. Comte, editor, Societe Ormeco et Imprimerie du Sud-Est Lyons, France, 1966, p, 167. Cleary, E.G., L.B. Sandberg, and D.S. Jackson, J, Cell Biol., z (1967) 469. Eastoe, J.E., Biochem. J., 61 (1955) 589. and V. Moret, J, Atheroscler. Res., 2 Gotte, L., Serafini-Fracas&ii, (1963) 244, Gotte, L., P. Stern, D.F. Elsden, and S.M. Partridge, Biochem, J., g (1963) 344. Heidrich, H.G. and L.K. Wynston, 2. Physiol. Chem., 342 (1965) 342, Miller, E.J. and H.M. Fullmer, J. Exp, Med., 123 (19m 1097. Partridge, Fed. Proc., 25 (1966) 1023 Partridge, S.M., H.F. DGis, and G.S. Adair, Biochem. J., 79 (1961) 15. Science, 161 v968) 475. Pinnell, S.R., G.R. Martin, and E.J. Miller, Sandberg, L.B., Ph.D. Thesis, Grad, Div. of the Univ. of Ore. Med. School, 1966. Sandberg, L.B. and E.G. Cleary, Biochim. Biophys. Acta, 154 (1968) 411. N. Weissman, and W.H. Carnes, Biochem, BiopF. Res. COPIOUS., Smith, D.W., 31 (1968) 309. 228