Study of membrane proteins from Microccus lysodeikticus using immunochemical methods]

Using immunoelectrophoresis, the antigenicity of various protein fractions of the Micrococcus lysodeikticus membranes was evaluated. It was shown that both the peripheral and integral membrane proteins possess the antigenic determinants. The antiserum exhausted by the M. lysodeikticus mebranes loses its ability to interact with intergral proteins, which are not solubilized by Triton X-100. It was thus assumed that the integral proteins are exposed on the membrane surface constantly or periodically and that there exist no proteins which are completely and permanently incorporated into the lipid bilayer. The respiratory chain of the M. lysodeikticus membrane is inhibited by membrane immunoglobulins by 50%. This is probably due to the presence in the membrane antiserum of antibodies specific to the respiratory chain enzymes. Evidence for this assumption can be derived from the fact that partially purified cytochrome b556 forms a precipitation zone with the membrane antiserum and that the activity of membrane NADH-dehydrogenase is inhibited by a monoserum against NADH-dehydrogenase.     

Solubilization of Chicken Feather Keratin by Ammonium Copper Hydroxide (Schweitzer’s Reagent)

Chicken feather powder was solubilized by Schweitzer’s reagent with shaking in the presence of air and the soluble feather keratin was prepared by dialyzing this extract against running water. Cystine residues in the starting feather keratin was converted to cysteic acid residues in the solubilized derivatives by air oxygen. Copper was bound fairly tightly to the solubilized protein and this copper-protein complex was separated into four fractions by CM- and DEAE-cellulose column chromatography. Each fraction had varied amount of bound copper, having a broad distribution of the molecular weight between 10,000 and 60,000 Sephadex column chromatographically. Although the amino acid composition of all separated feather keratin fractions were quite similar, the different electrophoretic patterns were observed among them by DISC electrophoresis.     

A soluble angiotensin II-binding protein from rabbit liver

An angiotensin II-binding activity has been detected in the 100,000 x g supernatant fraction of rabbit liver. The total amount of binding activity in this fraction was substantially greater than that which could be solubilized from hepatic particles by treatment with digitonin. The crude soluble binding activity resembled the binding protein which had been purified from the particles in several respects. First, binding required the presence of p-chloromercuriphenylsulfonic acid and bound angiotensin II was released by dithiothreitol. Second, the molecular weight of the responsible protein cross-linked to radioiodinated angiotensin II was about 75,000 in the reduced, denatured state. Finally, guinea pig antiserum raised against the binding protein that had been purified from particles reacted identically with the soluble and solubilized activities.     

Epithelial Metaplasia Induced Amnionic Ectoderm by the Dermis of Chicken Embryos1

Amnionic ectoderm of 6.8-day chicken embryos was associated with 6.8-day dorsal dermis or 13–15-day scale dermis and cultured on host chorio-allantoic membrane for 8 days. The amnionic ectoderm, recombined and cultured with the dorsal dermis, developed feather filaments consisted of a feather root, a horny sheath, and barb ridges. With several feather keratin-specific monoclonal antibodies (4E12 and 1F3), these structures in the induced feather filaments were shown to express feather-specific keratin antigens. The amnionic ectoderm, recombined and cultured with the shank dermis, became stratified squamous and developed scales. The scales were keratinized and their surface reacted only weakly with the monoclonal antibodies specific for the feather keratins. However, 1F3 reacted with two polypeptides in the cytoskeletal fraction of the scales, but not of the feather filaments. The results confirm our previous findings from in vitro experiments with the proamnionic ectoderm (Mizuno, 1970, 1972).     

A comparison of genomic coding sequences for feather and scale keratins: structural and evolutionary implications.

DNA sequences have been obtained for embryonic chick feather and scale keratin genes. Strong homologies exist between the protein coding regions of the two gene types and between the deduced amino acid sequences of the keratin proteins. Scale keratins are larger than feather keratins and the size difference is mainly attributable to four 13-amino acid repeats between residues 77 and 128 which compose a peptide sequence rich in glycine and tyrosine. The strong similarities between the two peptide structures for feather and scale in the homologous regions suggests a similar conformation within the protein filaments. A likely consequence is that the additional repeat region of the scale protein is located externally to the core filament. Tissue-specific features of filament aggregation may be attributable to this one striking sequence difference between the constituent proteins. It is believed that the genes share a common ancestry and that feather-like keratin genes may have evolved from a scale keratin gene by a single deletion event.     

Specific recognition of the neuronal cell surface by an antiserum raised plasma membrane preparations of immature rat cerebellum

A brain specific antiserum was prepared by immunizing rabbits with a crude membrane fraction from 8-day old rat cerebella. In immunofluorescence studies the antiserum labeled the perikarya and processes of cultured cerebellar neurones. In contrast, other cell types, encountered in cerebellar cultures including astrocytes, endothelial cells and fibroblasts, were consistently unstained. The antiserum when used in crossed immunoelectrophoresis with Triton X-100 solubilized brain extracts reacted predominantly with one antigen that could be identified as the D2 protein.This paper is dedicated to Dr. Derek Richter on his seventy-fifth birthday.     

Cytochemical and molecular characteristics of the process of cornification during feather morphogenesis

Feathers are the most complex epidermal derivatives among vertebrates. The present review deals with the origin of feathers from archosaurian reptiles, the cellular and molecular aspects of feather morphogenesis, and focus on the synthesis of keratins and associated proteins. Feathers consist of different proteins among which exists a specialized group of small proteins called beta-keratins. Genes encoding these proteins in the chick genome are distributed in different chromosomes, and most genes encode for feather keratins. The latter are here recognized as proteins associated with the keratins of intermediate filaments, and functionally correspond to keratin-associated proteins of hairs, nails and horns in mammals. These small proteins possess unique properties, including resistance and scarce elasticity, and were inherited and modified in feathers from ancestral proteins present in the scales of archosaurian progenitors of birds. The proteins share a common structural motif, the core box, which was present in the proteins of the reptilian ancestors of birds. The core box allows the formation of filaments with a different molecular mechanism of polymerization from that of alpha-keratins. Feathers evolved after the establishment of a special morphogenetic mechanism gave rise to barb ridges. During development, the epidermal layers of feathers fold to produce barb ridges that produce the ramified structure of feathers. Among barb ridge cells, those of barb and barbules initially accumulate small amounts of alpha-keratins that are rapidly replaced by a small protein indicated as “feather keratin”. This 10 kDa protein becomes the predominant form of corneous material of feathers. The main characteristics of feather keratins, their gene organization and biosynthesis are similar to those of their reptilian ancestors. Feather keratins allow elongation of feather cells among supportive cells that later degenerate and leave the ramified microstructure of barbs. In downfeathers, barbs are initially independent and form plumulaceous feathers that rest inside a follicle. Stem cells remain in the follicle and are responsible for the regeneration of pennaceous feathers. New barb ridges are produced and they merge to produce a rachis and a flat vane. The modulation of the growth pattern of barb ridges and their fusion into a rachis give rise to a broad variety of feather types, including asymmetric feathers for flight. Feather morphogenesis suggests possible stages for feather evolution and diversification from hair-like outgrowths of the skin found in fossils of pro-avian archosaurians.     

Immunochemical characterization of cell wall protein antigen purified from the cell wall autolysate of Clostridium botulinum type A.

The cell wall protein antigen was solubilized from the isolated cell walls of Clostridium botulinum type A by autolysis and purified by diethylaminoethyl-cellulose column chromatography followed by gel filtration on Sephadex G-150. The two fractions showed a high degree of the serological activity and produced a main fused precipitin line in immunodiffusion tests against the homologous antiserum. The fact that antigenic fractions contained various kinds of amino acids but no detectable amounts of amino sugars or carbohydrates suggests that the antigens were principally composed of proteins. The protein antigen possessed multiple antigenic components in immunoelectrophoresis. As serological activity, the antigen was heat-stable and resistant to tryptic digestion but sensitive to the actions of pronase, nagarse or pepsin. The protein antigen appeared to be responsible for the common antigenicity among the proteolytic strains of C. botulinum.     

Immunochemical Characterization of Cell Wall Protein Antigen Purified from the Cell Wall Autolysate of Clostridium botulinum Type A

The cell wall protein antigen was solubilized from the isolated cell walls of Clostridium botulinum type A by autolysis and purified by diethylaminoethyl-cellulose column chromatography followed by gel filtration on Sephadex G-150. The two fractions showed a high degree of the serological activity and produced a main fused precipitin line in immunodiffusion tests against the homologous antiserum. The fact that antigenic fractions contained various kinds of amino acids but no detectable amounts of amino sugars or carbohydrates suggests that the antigens were principally composed of proteins. The protein antigen possessed multiple antigenic components on immunoelectrophoresis. As serological activity, the antigen was heat-stable and resistant to tryptic digestion but sensitive to the actions of pronase, nagarse or pepsin. The protein antigen appeared to be responsible for the common antigenicity among the proteolytic strains of C. botulinum.     

茶毛虫核型多角体病毒的血清学特性

用免疫双扩散、对流免疫电泳、酶联免疫吸附试验(ELISA),固相免疫电镜(SPIEM)等技术,对茶毛虫核型多角体病毒(EpNPV)的抗原特性及与其它10种核型多角体病毒的血清学关系进行分析。结果表明,EpNPV粒子的抗血清只能与EpNPV粒子起反应,不与EpNPV的多角体蛋白及其它10种昆虫核型多角体病毒(NPV)粒子发生交叉反应;EpNPV多角体蛋白抗血清除了和其同源的多角体蛋白起反应外,还能和其它两种NPV的多角体蛋白起反应。以上结果说明了EpNPV的结构蛋白具有较高的抗原特异性,而多角体蛋白则没有种间特异性。同时将固相免疫电镜技术应用到昆虫病毒的血清学检测中,取得了较为理想的结果。     

The cDNA sequence of a human epidermal keratin: divergence of sequence but conservation of structure among intermediate filament proteins

We have determined the DNA sequence of a cloned cDNA that is complementary to the mRNA for the 50 kilodalton (kd) human epidermal keratin. This provides the first amino acid sequence for a cytoskeletal keratin. Comparison of this sequence with those of other keratins reveals an evolutionary relationship between the cytoskeletal and the microfibrillar keratins, but shows no homology to matrix or feather keratins. The 50 kd keratin shares 28%-30% homology with partial sequences of other intermediate filament proteins, which suggests that keratins may be the most distantly related members of this class of fibrous proteins. Our computer analyses predict that the 50 kd keratin contains two long alpha-helical domains separated by a cluster of helix-inhibitory residues in the middle of the protein. These findings indicate that despite major sequence divergence among intermediate filament proteins, they retain sequences compatible with secondary structural features that appear to be common to all of them.     

禽多杀性巴氏杆菌P1059成熟黏附蛋白的原核表达、纯化和抗原性检测

目的：建立rCPM36在大肠杆菌中的表达体系,纯化表达产物并检测其抗原性。方法：运用PCR方法从禽多杀性巴氏杆菌国际标准株P1059基因组中扩增出编码36kDa成熟黏附蛋白的cpm36基因,构建原核表达载体pQE30-cpm36,转化到大肠杆菌M15中并诱导表达目的蛋白,用镍离子螯合层析柱纯化目的蛋白及制备其抗体,Western印迹分析其抗原性。结果：SDS-PAGE结果显示目标蛋白以可溶性形式表达在大肠杆菌M15细胞质中,其相对分子质量为37kDa,Western印迹结果表明表达蛋白具有良好的抗原性。结论：成功构建出原核表达载体并实现了目的蛋白表达,用镍离子螯合层析柱纯化得到具有抗原性的蛋白,为进一步开展禽多杀性巴氏杆菌黏附因子和保护性抗原的研究奠定基础。     

Origin of feathers: Feather beta (beta) keratins are expressed in discrete epidermal cell populations of embryonic scutate scales

The feathers of birds develop from embryonic epidermal lineages that differentiate during outgrowth of the feather germ. Independent cell populations also form an embryonic epidermis on scutate scales, which consists of peridermal layers, a subperiderm, and an alpha stratum. Using an antiserum (anti-FbetaK) developed to react specifically with the beta (beta) keratins of feathers, we find that the feather-type beta keratins are expressed in the subperiderm cells of embryonic scutate scales, as well as the barb ridge lineages of the feather. However, unlike the subperiderm of scales, which is lost at hatching, the cells of barb ridges, in conjunction with adjacent cell populations, give rise to the structural elements of the feather. The observation that an embryonic epidermis, consisting of peridermal and subperidermal layers, also characterizes alligator scales (Thompson, 2001. J Anat 198:265-282) suggests that the epidermal populations of the scales and feathers of avian embryos are homologous with those forming the embryonic epidermis of alligators. While the embryonic epidermal populations of archosaurian scales are discarded at hatching, those of the feather germ differentiate into the periderm, sheath, barb ridges, axial plates, barbules, and marginal plates of the embryonic feather filament. We propose that the development of the embryonic feather filament provides a model for the evolution of the first protofeather. Furthermore, we hypothesize that invagination of the epidermal lineages of the feather filament, namely the barb ridges, initiated the formation of the follicle, which then allowed continuous renewal of the feather epidermal lineages, and the evolution of diverse feather forms.     

Identification and characterization of the ligand binding subunit of a kainic acid receptor using monoclonal antibodies and peptide mapping

Monoclonal antibodies (mAb) and a polyclonal antiserum were produced against a kainic acid receptor (KAR) purified from frog brain. Several of the mAb and the antiserum immunoprecipitated [3H]kainic acid binding activity from solubilized preparations of frog brain and labeled a group of proteins on immunoblots that migrated at Mr = 48,000. These results confirm that the ligand binding subunit of the frog brain KAR is contained in the Mr = 48,000 proteins. Immunoblots from different frog tissues demonstrated that the antibody reactivity was highly concentrated in the frog nervous system with no detectable immunoreactivity observed in non-neuronal tissues. The purified KAR was radioiodinated and subjected to two-dimensional gel electrophoresis and autoradiography. A series of proteins was detected at Mr = 48,000 with isoelectric points from 5.5 to 6.3. The anti-KAR mAb and the antiserum reacted with the same group of proteins from frog whole brain after separation by two-dimensional gel electrophoresis. Peptide maps of the 125I-labeled KAR separated by two-dimensional gel electrophoresis demonstrated that the group of proteins clustered at Mr = 48,000 is homologous. mAb KAR-B1 reacted on immunoblots with a protein in rat brain with a Mr = 99,000. This protein comigrated with an unreduced form of the KAR in frog brain. It was present in rat cerebral cortex, hippocampus, and cerebellum but was not detected in thalamus, globus pallidus, or brain stem, nor was it detected in rat non-neuronal tissues. The presence of the Mr = 99,000 immunoreactive polypeptide in discrete areas of rat brain suggests that this protein may be part of a mammalian KAR or a related receptor.     

The Expression of Beta ({beta}) Keratins in the Epidermal Appendages of Reptiles and Birds

The integuments of extant vertebrates display a variety of epidermalappendages whose patterns, morphology and terminal differentiation(epidermal keratins) depend upon interactions between ectodermal(epidermis) and mesodermal (dermis) tissues. In reptiles andbirds, appendage morphogenesis precedes terminal differentiation.Studies have demonstrated that appendage morphogenesis influencesthe expression of the appendage specific keratin genes. However,little is known about the nature of the structural genes expressedby the epidermal appendages of reptiles. How pattern formationand/or appendage morphogenesis influence terminal differentiationof reptilian appendages is not known. The epidermal appendages of reptiles and birds are characterizedby the presence of both alpha () and beta (ß) typekeratin proteins. Studies have focused on the genes of avianß keratins because they are the major structural proteinsof feathers. The occurrence of ß keratin proteinsin the scales and claws of both birds and reptiles and theirimmunological cross-reactivity suggest that the genes for reptilianß keratins may be homologous with those of birds.In bird appendages, the ß keratins are the productsof a large family of homologous genes. Specific members of thisgene family are expressed during the development of each appendage.Recent sequence analyses of feather ß keratins, fromdifferent orders of birds, demonstrate that there is more diversityat the DNA level than was implied by earlier protein sequencingstudies. Immunological techniques show that the same antibodies thatreact with the epidermal ß keratins of the chicken(Gallus domesticus) react with the epidermal ß keratinsof American alligators (Alligator mississippiensis). Furthermore,a peptide sequence (20 amino acids) from an alligator claw ßkeratin is similar to a highly conserved region of avian claw,scale, feather, and feather-like ß keratins. Theseobservations suggest that the ß keratin genes of avianepidermal appendages have homologues in the American alligator.Understanding the origin and evolution of the ß keratingene families in reptiles and birds will undoubtedly add toour understanding of the evolution of skin appendages such asscales and feathers.     

Avian feather development: relationships between morphogenesis and keratinization

Morphogenesis and expression of the alpha and beta keratin polypeptides are controlled by epidermal-dermal interactions during development of avian skin derivatives. We have examined the relationship between morphogenesis of the embryonic feather and expression of the feather alpha and beta keratins by routine histology, indirect-immunofluorescence, and SDS-PAGE. Initially beta keratins are expressed only in the feather sheath. Following barb ridge morphogenesis beta keratins can be detected in the barb ridge, coincident with the differentiation of barb ridge cells into eight distinct morphological types. Beta keratinization occurs in gradients; from feather apex to base, and from periphery of the barb ridge to the interior. The onset of beta keratinization in the barb ridges is paralleled by an increase in the major feather beta keratin polypeptides, as detected by SDS-PAGE. The alpha keratins are present in both the periderm and feather sheath at early stages of feather development, but become greatly reduced after hatching, when the down feather emerges from the sheath.     

Immunological properties of gap junction protein from mouse liver

Hepatic gap junctions were purified as plaques from BALB/c mice and separated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate (SDS). Antisera were raised in rabbits and rats against gap junction plaques as well as protein bands of the following apparent molecular weights: 44K to 49K ("dimer" proteins), 26K, and 21K. Using an enzyme immunoassay, we found that the reactivities of the different antisera towards gap junction plaques decreased in the following order: anti-plaque antisera, anti-26K antisera, anti-"dimer" protein antisera, and anti-21K antisera. The gap junction protein bands separated by SDS-polyacrylamide gel electrophoresis were transferred by blotting onto nitrocellulose paper and the immunological cross-reactivities were compared: the anti-26K antisera reated with the dimer protein bands and the 26K band but did not cross-react with the 21K protein band. The rabbit anti-21K antiserum reacted weakly with the 21K protein. The missing immunological cross-reaction of the 26K and the 21K protein band can be most easily explained if both proteins were independent of each other. No inhibition of metabolic cooperation between fibroblastoid mouse 3T6 cells was observed in the presence of Fab fragments prepared from rabbit antiplaque antiserum or from rabbit anti 26K antiserum. When the total proteins of plasma membranes from mouse liver were separated by SDS-polyacrylamide electrophoresis, only the 26K protein reacted with rabbit anti 26K antiserum. This result opens the possibility for direct quantitation of gap junction protein in tissues and cell fractions.     

Solubilization of Feather Keratin by a Copper-amine Complex

Chicken feather keratin was solubilized by cupri-ethylenediamine treatment and the solubilized products were separated into acidic and basic fractions by ion exchangers. In the solubilized products which had a molecular weight between 10,000 and 60,000, all the original cystine residues disappeared and cysteic acid residues were recovered instead of them but partly. The cupri-ethylenediamine reagent which catalyzed air-oxidation of cystine residues in keratin was removable mostly from the products by dialysis against water. The common copper-amine complexes were ineffective to solubilize feather keratin except for Schweitzer’s reagent. One strongly basic, unusual amino acid was detected in the basic solubilized fraction. This amino acid was eluted after arginine by usual column chromatography.     

Isolation of messenger RNA coding for the "fast" protein of embryonic chick feathers.

The messenger RNA coding for the "Fast" protein of embryonic chick feathers has been purified from the overwhelming relative amounts of keratin mRNA which are present in the developing feathers. The "Fast" protein mRNA represents about 4-8% of the total mRNA population of the feather. Despite differences between the size of the "Fast" proteins and the keratins the two mRNA species are very similar in molecular weight as judged by electrophoresis under denaturing conditions. However, by electrophoresis in 8 M urea gels at 55 degrees C, the "Fast" protein mRNA could be separated from keratin mRNA, presumably reflecting differences in messenger RNA secondary structure.