Avian thymic hormone (ATH) is a parvalbumin

Amino acid sequence analysis of a protein from chicken thymus tissue which promotes immunological maturity in chicken bone marrow cells in culture has established sequences of a 45-residue fragment, a 24-residue fragment and a 9-residue and an 8-residue peptide. Independent comparison of the 45- and 24-residue fragments with known amino acid sequences by computer search has unequivocally identified avian thymic hormone as a parvalbumin. This is the first demonstration that a protein previously identified by a biological function is a parvalbumin.     

Parvalbumin isoforms in chicken muscle and thymus. Amino acid sequence analysis of muscle parvalbumin by tandem mass spectrometry

Parvalbumins are high-affinity Ca(2+)-binding proteins characterized by an EF-hand structure. Muscles of lower vertebrates contain up to five isoparvalbumins whereas higher vertebrates were believed to contain only one isoform per species. Recently Brewer et al. [Brewer, J.M., Wunderlich, J.K., & Ragland, W. (1990) Biochimie 72, 653-660] purified and sequenced a protein that they named avian thymic hormone, from chicken thymus. This protein, promoting immunological maturation of bone marrow cells in culture, was identified as a parvalbumin. The amino acid composition of this thymic parvalbumin was, however, considerably different from those of chicken muscle parvalbumin [Strehler, E.E., Eppenberger, H.M., & Heizman, C.W. (1977) FEBS Lett. 75, 127-133], suggesting the existence of two tissue-specific parvalbumins in chicken. We purified parvalbumin from chicken muscle, determined its complete amino acid sequence by tandem mass spectrometry, and showed that this protein is rather homologous to muscle parvalbumins from other species but different in 45 positions from the thymic parvalbumin. We discuss the possibility that a parvalbumin gene family might exist in higher vertebrates, expressed in a tissue-specific and developmentally regulated manner.     

Partial nucleotide sequence of the parvalbumin from chicken thymus designated "avian thymic hormone"

The incomplete amino acid sequence of the protein identified as avian thymic hormone was recently reported [Brewer et al. (1989), Biochem. Biophys. Res. Commun. 160, 11555-1161], and a very high degree of homology to the parvalbumins was apparent. Using mixed oligonucleotide primers based on the reported protein sequence, we have succeeded in amplifying and cloning a 188 bp fragment of the coding region for this protein, beginning with double-stranded cDNA prepared from chicken thymus mRNA. The translated nucleotide sequence of this fragment and the reported amino acid sequence display substantial disagreement. Most notably, the nucleotide sequence indicates that the CD site of avian thymic hormone is a typical parvalbumin CD site.     

Comparison of the amino acid sequences of tissue-specific parvalbumins from chicken muscle and thymus and possible evolutionary significance

Chicken leg muscle parvalbumin was digested with cyanogen bromide or trypsin or trypsin after citraconylation. Peptides isolated by reverse phase HPLC at pH 7.0 were subjected to acid hydrolysis and amino acid analysis and, in some cases, sequencing. The chicken muscle parvalbumin amino acid sequence has ca. 80% sequence identity with alpha-type parvalbumins from mammalian (rabbit, human and rat) muscle. By contrast, the chicken thymus parvalbumin ("avian thymic hormone") sequence is very similar to reptile (turtle, salamander and frog) muscle beta-type parvalbumins. We hypothesize that the evolutionary appearance of the warm-blooded reptiles was accompanied by recruitment of the beta parvalbumin isozyme for promotion of lymphocyte maturation.     

Metal ion-binding properties of avian thymic hormone

Lanthanide ion luminescence studies and 45Ca2(+)-binding measurements were used to study the metal ion-binding properties of avian thymic hormone. The procedure used to isolate the protein--involving heat-treatment at 80 degrees C, trichloroacetic acid precipitation, DEAE-agarose chromatography, and gel filtration--affords material that is deemed homogeneous by sodium dodecyl sulfate-polyacrylamide gel electrophoresis as well as the absence of a detectable tryptophan signal in the fluorescence emission spectrum. Avian thymic hormone exhibits a pI = 4.35 when subjected to isoelectric focusing through polyacrylamide gels. The two ion-binding sites are indistinguishable in their interactions with Ca2+ and Mg2+, displaying KCa = 8 nM and KMg = 68 microM. The Eu3+ 7Fo----5Do excitation spectrum at pH 6 displays a peak at 5795.4 A, with a shoulder at 5792.8 A and is replaced at higher pH values by a broader spectrum with a maximum at 5784.8 A and a shoulder at 5777.1 A. The pKa governing this spectral interconversion is 8.21. All of these properties are very similar to those observed with other parvalbumins. However, polyclonal antibodies to avian thymic hormone do not cross-react with the parvalbumin from chicken leg muscle, as judged by Western blot analysis-further evidence that avian thymic hormone and the muscle-associated chicken parvalbumin are indeed distinct proteins.     

The amino acid sequence of avian thymic hormone, a parvalbumin

The complete amino acid sequence of 'avian thymic hormone' (ATH), a protein from thymus tissue that appears to promote immune maturation in chicken bone marrow cells in culture, is presented. The sequence was obtained from sequences of ATH peptides isolated by HPLC after tryptic, chymotryptic, peptic or S aureus V8 protease digestions. The protein is a parvalbumin consisting of 108 residues with a blocked amino terminus, a single cysteine, tyrosine, proline and arginine and no histidine, methionine or tryptophan. This is the first amino acid sequence of a parvalbumin which is not derived from muscle tissue.     

Differential cytoplasmic and whole cellular expression of histone H1 within the avian bursa of Fabricius

Bursal anti-steroidogenic peptide (BASP), purified from the chicken bursa of Fabricius (BF), has been previously demonstrated to be a potent and efficacious inhibitor of steroid hormone biosynthesis from chicken ovarian, and both mammalian and avian adrenal cells in vitro. Other studies have demonstrated that BASP can markedly reduce avian and mammalian mitogen-stimulated lymphocyte proliferation. Recent studies have indicated that BASP has a structural and functional relationship with histone H1. Immunohistochemical studies using a monoclonal antibody, which is known to recognize a common histone H1 epitope from several plant and animal species identified the protein within the cytoplasm and nucleus of distinct cells within both the cortex and medulla of all BF follicles. Additionally, epithelial cells within the BF expressed the protein strongly in the cytoplasm with reduced nuclear staining. In contrast, the same antibody did not recognize the protein in thymus of the same animals. The differential expression of histone H1 immunoreactivity within selected cells of the BF may support a previous proposed role of histone H1 in extranuclear and extracellular signaling in chickens and possibly other species.     

Chicken parvalbumin. Comparison with parvalbumin-like protein and three other components (Mr = 8,000 to 13,000).

Procedures for a rapid isolation and purification of parvalbumin (Mr = 12,600), parvalbumin-like protein (Mr = 12,800), and three other polypeptides with molecular weights of 12,400 (Component 1), 11,700 (Component 2), and 8,000, respectively, from chicken leg muscle, are described. A direct comparison of parvalbumin with these other proteins showed distinct differences in the amino acid compositions, charge, and immunological behavior. Parvalbumin has two high affinity sites for Ca2+ with a KDiss less than or equal to 10(-6) M (Blum, H. E., Lehky, P., Kohler, L., Stein, E.A., and Fischer, E. H. (1977) J. Biol. Chem. 252, 2834-2838), in contrast to parvalbumin-like protein. Components 1 and 2, and the Mr = 8,000 protein, where only low affinity sites for Ca2+ could be detected (KDiss greater than 10(-3) M). From our results it is concluded that the co-extracted proteins do not constitute isoproteins of parvalbumin. The very low affinity for Ca2+ suggests that these proteins are not involved in processes of Ca2+ transport or Ca2+ regulation as proposed for parvalbumin. Parvalbumin could not be localized within isolated myofibrils and also did not accumulate in primary myogenic cell cultures together with proteins forming the myofibrillar structure. Parvalbumin was not even detected in myotubes in which myofibrils and sarcoplasmatic reticulum were already assembled and functioning. Parvalbumin (or cross-reacting material) was detected in leg muscle and brain 1 day after hatching of the chick. Possible roles for parvalbumin are discussed.     

Site-specific N-glycosylation of chicken serum IgG

Avian serum immunoglobulin (IgG or IgY) is functionally equivalent to mammalian IgG but has one additional constant region domain (CH2) in its heavy (H) chain. In chicken IgG, each H-chain contains two potential N-glycosylation sites located on CH2 and CH3 domains. To clarify characteristics of N-glycosylation on avian IgG, we analyze N-glycans from chicken serum IgG by derivatization with 2-aminopyridine (PA) and identified by HPLC and MALDI-TOF-MS. There were two types of N-glycans: (1) high-mannose-type oligosaccharides (monoglucosylated 26.8%, others 10.5%) and (2) biantennary complex-type oligosaccharides (neutral, 29.9%; monosialyl, 29.3%; disialyl, 3.7%) on molar basis of total N-glycans. To investigate the site-specific localization of different N-glycans, chicken serum IgG was digested with papain and separated into Fab [containing variable regions (VH + VL) + CH1 + CL] and Fc (containing CH3 + CH4) fragments. Con A stained only Fc (CH3 + CH4) and RCA-I stained only Fab fractions, suggesting that high-mannose-type oligosaccharides were located on Fc (CH3 + CH4) fragments, and variable regions of Fab contains complex-type N-glycans. MS analysis of chicken IgG-glycopeptides revealed that chicken CH3 domain (structurally equivalent to mammalian CH2 domain) contained only high-mannose-type oligosaccharides, whereas chicken CH2 domain contained only complex-type N-glycans. The N-glycosylation pattern on avian IgG is more analogous to that in mammalian IgE than IgG, presumably reflecting the structural similarity to mammalian IgE.     

Determination of and corrections to sequences of turkey and chicken troponins-C. Effects of Thr-130 to Ile mutation on Ca2+ affinity

Reported differences in the primary structures of chicken muscle troponin C (Wilkinson, J.M. (1976) FEBS Lett. 70, 254-256) and recombinant protein deduced from a chick muscle cDNA (Reinach, F.C. and Karlsson, R. (1988) J. Biol. Chem. 263, 2371-2376) have been reinvestigated. The complete amino acid sequence of turkey muscle troponin C has also been elucidated. Residue 100, originally reported as Asp in the chicken muscle protein, is shown to be Asn in all three structures. The three amino acid sequences are identical except as follows: 1) the blocked NH2-terminal Ala at residue 1 of the chicken protein is replaced by nonblocked Met-Ala in the recombinant protein and by nonblocked Pro in turkey troponin-C; 2) residue 130 is Thr in both avian muscle proteins but Ile in the recombinant protein; 3) Asp-133 in the chicken muscle and recombinant troponins-C is replaced by Glu in the turkey protein; 4) residue 99, originally identified as Glu in the x-ray structure of the turkey protein, is shown to be Ala in all three proteins. Calcium titration of the metal-induced conformational transition of the protein as monitored by far UV CD measurements indicated a significant decrease in Ca2+ affinity of the high-affinity sites in the case of the recombinant protein as compared with the chicken muscle protein. Both pairs of sites showed high cooperativity. That this decreased Ca2+ affinity could be attributed to different amino acid residues at position 130 and not to the differences at the NH2 termini was confirmed by site-specific mutation of Ile-130 to Thr in the recombinant protein. The mutated recombinant protein now titrated identically to the chicken muscle protein. Thr-130, whereas over 21 A from the metal of sites III and IV, is involved in a hydrogen bonding network with structured water and the NH2-terminal region of helix G.     

Fluorescence studies of the calcium binding to whiting (Gadus merlangus) parvalbumin

The calcium binding by parvalbumin of whiting (Gadus merlangus) has been studied using tryptophanyl fluorescence characteristics. Titration of Ca2+-free parvalbumin with Ca2+ leads to a very pronounced blue shift, narrowing and intensification of the fluorescence spectrum. These spectral changs proceed in two stages reflecting the existence of at least three forms which can be interpreted as (a) the protein without Ca2+, (b) with one Ca2+ and (c) with two bound Ca2+ ions/molecule. The fluorescence of these forms has been identified and the fluorescence spectra measured at varied Ca2+ concentrations were resolved into three components corresponding to these spectral forms. The dependence of the relative concentration of the three fomrs on Ca2+ concentrations agree well with the two-step binding of Ca2+ to parvalbumin: Protein + Ca in equilibrium K1 protein x Ca; Protein x Ca + Ca in equilibrium K2 Ca x protein x Ca. The equilibrium binding constants K1 and K2 obtained by the computer fit are approximately 5 X 10(8) M-1 and 6 X 10(6) M-1. This scheme and the K1 and K2 value are in a good agreement with the independent experimental data resulting from EGTA titration of Ca2+-saturated parvalbumin and pH titratin of parvalbumin in the presence of EGTA and CA2+.     

Structure and properties of avian small heat shock protein with molecular weight 25 kDa

The primary structure of chicken small heat shock protein (sHsp) with apparent molecular weight 25 kDa was refined and it was shown that this protein has conservative primary structure 74RALSRQLSSG(83) at Ser77 and Ser81, which are potential sites of phosphorylation. Recombinant wild-type chicken Hsp25, its three mutants, 1D (S15D), 2D (S77D+S81D) and 3D (S15D+S77D+S81D), as well as delR mutant with the primary structure 74RALS-ELSSG(82) at potential sites of phosphorylation were expressed and purified. It has been shown that the avian tissues contain three forms of Hsp25 having pI values similar to that of the wild-type protein, 1D and 2D mutants that presumably correspond to nonphosphorylated, mono- and di-phosphorylated forms of Hsp25. Recombinant wild-type protein, its 1D mutant and Hsp25, isolated from chicken gizzard, form stable high molecular weight oligomeric complexes. The delR, 2D and 3D mutants tend to dissociate and exist in the form of a mixture of high and low molecular weight oligomers. Point mutations mimicking phoshorylation decrease chaperone activity of Hsp25 measured by reduction of dithiothreitol induced aggregation of alpha-lactalbumin, but increase the chaperone activity of Hsp25 measured by heat induced aggregation of alcohol dehydrogenase. It is concluded that avian Hsp25 has a more stable quaternary structure than its mammalian counterparts and mutations mimicking phosphorylation differently affect chaperone activity of avian Hsp25, depending on the nature of target protein and the way of denaturing.     

High levels of CD45 are coordinately expressed with CD4 and CD8 on avian thymocytes.

In this paper we describe the avian homolog of mammalian CD45. We show that this Ag is expressed on all leukocytes but not on erythroid cells or their immediate precursors. Immunoprecipitations demonstrated that B lineage cells from the bursa of Fabricius expressed a higher molecular mass variant (215 kDa) than did T lineage cells from the thymus (190 kDa), and crucially, these high molecular mass molecules had intrinsic phosphotyrosine phosphatase activity characteristic of mammalian CD45. We show that levels of CD45 expression as detected by mAb LT40 in the avian thymus are heterogeneous and further that mAb LT40 can deplete all phosphotyrosine phosphatase activity from thymocyte membrane preparations. Therefore total levels of CD45 are heterogeneous among avian thymocytes. Specifically, 87 to 89% of thymocytes expressed fourfold higher levels of surface CD45 (CD45hi) than the remaining 11 to 13% (CD45lo). The CD45lo population contained exclusively thymocytes with the phenotype CD3-4-8lo, characteristic of the immediate precursors to the CD3-4+8+ thymic population which are CD45hi. The shift from low to high levels of surface CD45 expression therefore occurred at the same stage as the transition from CD4-8lo to CD4+8+ and before the expression of CD3. The protein tyrosine kinase activity associated with CD4 and CD8 (p56lck) and the phosphatase activity of CD45 have been implicated elsewhere in jointly regulating peripheral T cell signal transduction and subsequent cellular responses. The coordinated expression of high levels of CD45 with both CD4 and CD8 in the avian thymus supports the possibility that these molecules may function together in regulating thymocyte growth and/or differentiation.     

Change in protein synthesis and enzyme activity in avian endocrine glands during ontogenesis

The synthesis of cytoplasmic proteins and the activity of cAMP-dependent protein kinase were studied in the thyroid gland and thymus of intact and irradiated (0.05 Gr) embryos and chicks. The increase in labeled amino acid incorporation into proteins of irradiated chicken endocrine organs during postnatal development was more apparent in thyrocytes. Stimulation of protein kinase activity in the thyroid gland and thymus was observed at the same periods of time. It was supposed that minor doses of ionizing radiation stimulate synthetic processes as well as phosphorylation of proteins responsible for differentiation of avian endocrine organs.     

Divalent ion-binding properties of the two avian beta-parvalbumins

Birds express three parvalbumins, one alpha isoform and two beta isoforms. The latter are known as avian thymic hormone (ATH) and avian parvalbumin 3. Although both were discovered in thymus tissue, and presumably function in T-cell maturation, they have been detected in other tissue settings. We have conducted detailed Ca2+- and Mg2+-binding studies on recombinant ATH and the C72S variant of CPV3, employing global analysis of isothermal titration calorimetry data. In Hepes-buffered saline, ATH binds Ca2+ with apparent microscopic binding constants of 2.4 +/- 0.2 x 10(8) and 1.0 +/- 0.1 x 10(8) M(-1). The corresponding values for CPV3-C72S are substantially lower, 4.5 +/- 0.5 x 10(7) and 2.4 +/- 0.2 x 10(7) M(-1), a 1.9-kcal/mol difference in binding free energy. Thus, the beta-parvalbumin lineage displays a spectrum of Ca2+-binding affinity, with ATH and the mammalian beta isoform at the high- and low-affinity extremes and CPV3 in the middle. Interestingly, despite its decreased Ca2+ affinity, CPV3-C72S exhibits increased affinity for Mg2+, relative to ATH. Whereas the latter displays Mg2+-binding constants of 2.2 +/- 0.2 x 10(4) and 1.2 +/- 0.1 x 10(4) M(-1), CPV3-C72S yields values of 5.0 +/- 0.8 x 10(4) and 2.1 +/- 0.3 x 10(4) M(-1).     

Nonmammalian vertebrate skeletal muscles express two triad junctional foot protein isoforms.

Mammalian skeletal muscles express a single triad junctional foot protein, whereas avian muscles have two isoforms of this protein. We investigated whether either case is representative of muscles from other vertebrate classes. We identified two foot proteins in bullfrog and toadfish muscles on the basis of (a) copurification with [3H]epiryanodine binding; (b) similarity to avian muscle foot proteins in native and subunit molecular weights; (c) recognition by anti-foot protein antibodies. The bullfrog and toadfish proteins exist as homooligomers. The subunits of the bullfrog muscle foot protein isoforms are shown to be unique by peptide mapping. In addition, immunocytochemical localization established that the bullfrog muscle isoforms coexist in the same muscle cells. The isoforms in either bullfrog and chicken muscles have comparable [3H]epiryanodine binding capacities, whereas in toadfish muscle the isoforms differ in their levels of ligand binding. Additionally, chicken thigh and breast muscles differ in the relative amounts of the two isoforms they contain, the amounts being similar in breast muscle and markedly different in thigh muscle. In conclusion, in contrast to mammalian skeletal muscle, two foot protein isoforms are present in amphibian, avian, and piscine skeletal muscles. This may represent a general difference in the architecture and/or a functional specialization of the triad junction in mammalian and nonmammalian vertebrate muscles.