Cloning and nucleotide sequence analysis of the cDNA of the immunoglobulin lambda light chain from the bovine udder

A cDNA library was constructed from the mRNA of bovine mammary gland which contained Ig lambda producing plasmacytes. Overlapping clones encompassing the major portion of the coding sequence of the Ig lambda mRNA were isolated and sequenced. Predicted amino acid sequence shows a mature polypeptide of 217 residues in which V, J and C regions can be distinguished. The constant region has greatest homology with human Ig lambda mRNA constant region. The area of the V region between CDR3 and CDR2 has also great homology with the same area of human lambda chain.     

Molecular cloning of a bovine immunoglobulin lambda chain cDNA

A cDNA library of the bovine mammary gland constructed in pBR322 was screened by mRNA hybrid-selected translation and by differential hybridization. Several immunoglobulin (Ig) lambda light-chain clones were identified and sequenced. Nucleotide sequence comparison of bovine and human Ig lambda chains showed a high degree of homology for constant regions and for J regions. The amino acid (aa) sequence encoded by the constant region of the bovine Ig lambda chain cDNA contains 107 aa with differences at 24 aa positions from the human Ig lambda chain. Three complementarity-determining regions (CDR1,2,3) characteristic of the variable region of bovine Ig lambda chain cDNA can be distinguished. The bovine and human sequences display good homology in the framework region 3 (FR3) but only patches of homology throughout the FR2 region. The 5' end of the bovine Ig lambda chain cDNA fragment of clone 1-14E contains five stop codons: two in CDR1, one in FR1 and two in the hydrophobic prepeptide region. These data suggest that the Ig lambda mRNA of clone 1-14E is transcribed from the V lambda pseudogene.     

Biochemical and genetic evidence for three transmembrane domains in the class I holin, lambda S

lambda S, the prototype class I holin gene, encodes three potential transmembrane domains in its 107 codons, whereas 21 S, the class II prototype spans only 71 codons and encodes two transmembrane domains. Many holin genes, including lambda S and 21 S, have the "dual-start" regulatory motif at the N terminus, suggesting that class I and II holins have the same topology. The primary structure of 21 S strongly suggests a bitopic "helical-hairpin" topology, with N and C termini on the cytoplasmic side of the membrane. However, lambda S chimeras with an N-terminal signal sequence show Lep-dependent function, indicating that the N-terminal domain of S requires export. Here the signal sequence chimera is shown to be sensitive to the missense change A52V, which blocks normal S function. Moreover, cysteine-modification studies in isolated membranes using a collection of S variants with single-cysteine substitutions show that the positions in the core of the 3 putative transmembrane domains of lambda S are protected. Also, S proteins with single-cysteine substitutions in the predicted cytoplasmic and periplasmic loops are more efficiently labeled in inverted membrane vesicles and whole cells, respectively. These data constitute direct evidence that the holin S(lambda) has three transmembrane domains and indicate that class I and class II holins have different topologies, despite regulatory and functional homology.     

Lambda H-lambda T 80 hybrid study of the DNA structural gene region in lambda and phi 80 phages

Hybrids lambda H lambda T80 are formed due to recombination of the phage lambda att80 and phi 80 prophage partially deleted in the region of structural genes. Genetic structure of 22 independently isolated lambda H lambda T80 hybrids was determined by the restriction method and it was shown that recombination took place in the genes A, C, D and H. The frequencies of hybrid formation diminish from 1.10(-3) to 4.10(-5) for this gene order, which suggests that the polar divergence of nucleotide sequencies in the region of structural genes exists. It was found that formation of hybrids with recombination in the region of "weak" homology (gene H) was possible only when the region of "strong" homology was present in the deleted phi 80 prophage to initiate recombination.     

The primary structure of the constant region of Basilea-rabbit immunoglobulin lambda-chains.

The amino acid sequence of the constant region of the immunoglobulin lambda-chain of the rabbit (C lambda) has been determined. This chain was obtained from a homogeneous anti-(type II pneumococcal polysaccharide) antibody fraction raised in Basilea rabbit 4548. The C lambda-region sequence was established by the analysis of tryptic and some overlapping chymotryptic peptides and partly by homology with known C lambda-region sequences of lambda-chains from other species. Peptides were isolated by a combination of methods including high-voltage paper electrophoresis, gel filtration and high-pressure liquid chromatography. The peptides were subjected to automated Edman degradation in the presence of Polybrene. The sequence showed no evidence of heterogeneity. Large interspecies similarities, as well as amino acid interchanges, are apparent among various C lambda regions; the degrees of homology between rabbit C lambda region and the C lambda region from human, porcine and murine chains are 72.6, 71 and 72% respectively. The similarity of lambda-chains of different species is much greater than that found between rabbit kappa- and lambda-chains (about 34% homology). Genetic implications of these results are discussed.     

Tests of the Double-Strand-Break Repair Model for Red-Mediated Recombination of Phage λ and Plasmid λdv

The double-strand-break repair (DSBR) model was formulated to account for various aspects of yeast mitotic and meiotic recombination. In this study three features of the DSBR model are tested for Red-mediated recombination between phage lambda and lambda dv, a plasmid that is perfectly homologous to about 10% of lambda. The results support the applicability of the DSBR model to lambda's Red system: (1) Creating a double-strand-break (DSB) within the region of homology shared by phage and plasmid increases their genetic interaction by about 20-fold. A DSB outside the region of shared homology has no such effect. (2) Both patches, i.e., simple marker rescue, and splices, i.e., co-integration of the phage and plasmid, are stimulated by a DSB in the region of shared homology. (3) Co-integrants harbor a duplication of the region of shared homology. Among co-integrants that were formed by the creation of a DSB, there is a preferential loss of whichever allele was in cis to a utilized cut site. The DSBR model as originally formulated involves the isomerization and cleavage of Holliday junctions to resolve the canonical intermediate. We propose as an alternative mechanism that a topoisomerase can resolve the canonical DSBR intermediate.     

Molecular cloning and characterization of rat contrapsin-like protease inhibitor and related proteins

A glycoprotein with Mr 63,000 purified from rat serum was found to inhibit trypsin activity but not chymotrypsin or elastase activity, resembling contrapsin purified from mouse serum. To obtain further information on the molecular structure, a cDNA clone (lambda CPi-21) for this contrapsin-like protease inhibitor was isolated from a rat liver cDNA library. The 1.6-kb cDNA insert contained an open reading frame that encodes a 416-residue polypeptide (CPi-21), in which the first 29 residues were suggested to comprise a signal peptide by comparison with the NH2-terminal sequence of the purified protein. The predicted structure also contained other peptide sequences determined by Edman degradation. Four potential N-linked glycosylation sites were found in the molecule, presumably accounting for the larger molecular mass of the mature form. Further screening of the cDNA library with a Pst-XbaI fragment (302 bp) of lambda CPi-21 as a probe yielded two other cDNA clones (lambda CPi-23 and lambda CPi-26), which encode 413-residue and 418-residue polypeptides, respectively. A comparison of their amino acid sequences revealed that CPi-21 has 89 and 71% homology with CPi-23 and CPi-26, respectively. The primary structure of each of the three proteins has about 70% homology with that of mouse contrapsin, in contrast to 43-46% homology with that of rat alpha 1-protease inhibitor. These results indicate that all the CPi proteins presented here belong to a subfamily of "serpins" of which mouse contrapsin was the first member to be identified.     

Primary structure of the variable region of an amyloidogenic Bence Jones protein NIG-77

The complete amino acid sequence of the variable region of a Bence Jones protein NIG-77 from an individual with myeloma-associated systemic amyloidosis has been determined. This protein represents a complete light chain consisting of 216 residues and it has a sequence characteristic of V lambda I subgroup, which is closely homologous to that of another amyloidogenic V lambda I Bence Jones protein NIG-51, differing by 20 of 111 residues (82% homology). In contrast, it differs by 29 residues (74% homology) to that of non-amyloidogenic V lambda I light chain NIG-64. This finding shows that, in accordance with our previous report(1), the V lambda I-related light chains can further be divided into two distinct subsubgroups, V lambda I-1 and V lambda I-2, and the latter property seems to be more prone in association with the amyloid process.     

Comparative study on the structure of the light chains of human immunoglobulins. II. Assignment of a new subgroup.

The primary structure of the variable region of the human lambda type Bence Jones protein NIG-48 was determined by analysis of the N-terminal sequence of the completely reduced and aminoethylated protein, as well as of five cyanogen bromide fragments. The variable region of NIG-48 contains 112 amino acid residues. The protein NIG-48, having a unique sequence of the variable region, a low degree of homology (about 50%) with lambda chains of the five other subgroups and the addition of two residues around 65, may represent a new subgroup, namely V lambda VI.     

Comparative studies on the structure of the light chains of human immunoglobulins. IV. Assignment of a subsubgroup

Amino acid sequence analysis was done on a human lambda Bence Jones protein NIG-64 with the major objective of determining the sequence of the variable region. Nineteen tryptic peptides covering 216 residues were isolated from the completely reduced and aminoethylated protein, and 17 of these were completely sequenced. These comprised the entire variable region and 11 from the constant region. For the remaining peptides covering the rest of the constant region, only partial sequences or the amino acid compositions were determined. All the tryptic peptides could be arranged in order on the basis of the above results and homology with other human lambda light chains of the same isotype. The sequence of the variable region of the protein is highly homologous with that of protein New of subgroup V lambda I as compared with other proteins of the same subgroup, suggesting that subgroup V lambda I may be further divided into subsubgroups, namely subsubgroups V lambda I-1 and V lambda I-2.     

Sequence of a secondary phage lambda attachment site located between the pentitol operons of Klebsiella aerogenes.

We have determined the nucleotide sequence of a secondary phage lambda attachment site (att) located between the structural genes of the ribitol and D-arabitol catabolic operons of Klebsiella aerogenes. The core region of this secondary attachment site (sequence: GGTTTTTTCGATTAT) shows considerable homology with the 15-base-pair core region common to both the phage att and the primary bacterial att of Escherichia coli K12 (sequence: GCTTTTTTACTAA); however, there is no such clear homology between the sequences flanking the cores of the primary att and this secondary att. Integration of phage lambda into the K. aerogenes secondary att occurred by recombination between the core region of the phage att and an oligo(T.A) stretch located within the K. aerogenes secondary att.