Distribution of immunoglobulin determinants on the surface of Xenopus laevis splenic lymphocytes.

The distribution of surface immunoglobulin (Ig) determinants on Xenopus laevis splenic lymphocytes after combination with divalent rabbit anti-Ig coupled to ferritin was studied. The electron micrographs showed the presence of immune complexes in 67% of lymphocytes treated at 0 degrees C-4 degrees C. The complexes were located all around the membrane and uniformly distributed in a random fashion. The variation of ferritin grain counts on cell sections is such, that the existence of two major subclasses of Ig-positive cells may be suggested. Raising the temperature produced a rapid interiorization of the complexes in vesicles without any previous aggregation to form a "cap" having occurred.     

Amino acid-sequence variability at the N-terminal extra piece of mouse immunoglobulin light-chain precursors of the same and different subgroups.

The proteins programmed in the wheat-germ cell-free system by the mRNA coding for the MOPC-63 mouse myeloma L (light) chain were labelled with six radioactive amino acids: [35S]methionine, [4,5-3H]leucine, [3,4-3H]proline, [3-3H]serine, [4,5-3H]isoleucine or [2,3-3H]alanine. Amino acid-sequence analyses showed that over 90% of the total cell-free product was one homogeneous protein, which corresponds to the MOPC-63 L-chain precursor. In this precursor an extra piece, 20 amino acid residues in length, precedes the N-terminus of the mature L chain. The extra piece contains one methionine residue at the N-terminus, six leucine residues, which are clustered in two triplets at positions 6, 7, 8 and 11, 12, 13, one proline residue at position 16, and one serine residue at position 18. The closely gathered leucine residues, as well as their abundance (30%), suggest that the extra-piece moiety is hydrophobic. In the precursors, the extra piece is coupled to the variable region of the L chain. Partial sequences of precursors of L chains of the same and different subgroups that were labelled with the above six radioactive amino acids indicate that the extra piece is part of the variable region. Thus the precursors of MOPC-63 and MOPC-321 L chains, which are of the same subgroup, have extra pieces of identical size (20 residues), and so far their partial sequences are also identical (see above). On the other hand, in the precursor of MOPC-41 L chain, which is of a different subgroup, the extra piece is 22 residues in length. Further, the sequence of the MOPC-41 extra piece differs in at least ten positions from sequences of the extra pieces of the precursors of MOPC-63 and MOPC-321 L chains.     

Ongoing diversification of the rearranged immunoglobulin light-chain gene in a bursal lymphoma cell line.

The chicken immunoglobulin light-chain gene (IgL) encodes only a single variable gene segment capable of recombination. To generate an immune repertoire, chickens diversify this unique rearranged VL gene segment during B-cell development in the bursa of Fabricius. Sequence analysis of IgL cDNAs suggests that both gene conversion events derived from VL segment pseudogene templates (psi VL) and non-template-derived single-base-pair substitutions contribute to this diversity. To facilitate the study of postrecombinational mechanisms of immunoglobulin gene diversification, avian B-cell lines were examined for the ability to diversify their rearranged IgL gene during in vitro passage. One line that retains this ability, the avian leukosis virus-induced bursal lymphoma cell line DT40, has been identified. After passage for 1 year in culture, 39 of 51 randomly sequenced rearranged V-J segments from a DT40 population defined novel subclones of the parental tumor. All cloned V-J segments displayed the same V-J joint, confirming that the observed diversity arose after V-J rearrangement. Most sequence variations that we observed (203 of 220 base pairs) appeared to result from psi VL-derived gene conversion events; 16 of the 17 novel single nucleotide substitutions were transitions. Based on these data, it appears that immunoglobulin diversification during in vitro passage of DT40 cells is representative of the diversification that occurs during normal B-cell development in the bursa of Fabricius.     

Identification of molecular markers associated with leptine in reciprocal backcross families of diploid potato

Solanum phureja clone 1-3 and S. chacoense clone 80-1 have a zero and high leptine content in their foliage, respectively. An F(1) hybrid (CP2) was intermediate for the trait, but self-incompatible. Two reciprocal backcross families, PBCp ( phu 1-3 x CP2) and PBCc (CP2 x phu 1-3), and a family of monoploids derived by anther culture of CP2, were characterized for leptine as the aglycon, acetylleptinidine (ALD), content in leaves by gas chromatography. ALD was present in 43 of 87 genotypes in the PBCp backcross, implying simple genetic control by a dominant gene. However, the ALD levels were low compared to CP2. In the PBCc backcross, only 7 of 42 genotypes expressed ALD at a level generally higher than in PBCp. This ratio was significantly different from the 1:1 segregation observed in the reciprocal backcross and suggests a cytoplasmic influence. ALD levels in the CP2 monoploids ranged from 0 to 8,968 &mgr;g.g(-1) of dry weight (dw) with 18 individuals expressing ALD and five with 0 ALD content. Ten high (mean ALD = 546 &mgr;g.g(-1) of dw) and ten low (mean ALD = 0) individual plants within PBCp and seven high (mean ALD = 3,037 &mgr;g.g(-1) of dw) and eight low (mean ALD = 0) individual plants within PBCc were used for bulk segregant analysis (BSA) using 214 RAPD (randomly amplified polymorphic DNA) primers. Three RAPD primers (OPQ-2, OPT-16 and OPT-20) amplified bands exclusively in bulks containing DNA mixes of high ALD producers in both PBCp and PBCc populations. These results suggest that these markers were associated in coupling to ALD content. ANOVAs for ALD content verified association between the markers and the trait. A CAPS (cleaved amplified polymorphic sequence) marker, GP82A, was also significantly associated with ALD production in both the monoploid and the PBCp populations. None of the RAPD markers was associated to ALD in the monoploids but one was associated in repulsion. The monoploid data indicate the likelihood of a recessive gene(s) that controls leptine production, but the backcross data indicate the action of modifying loci.     

Sequence studies on the heavy chain of rabbit immunoglobulin A of different alpha-locus allotypes.

The amino acid sequence was determined of part of the variable region of heavy chain from rabbit immunoglobulin A of allotypes a1 and a3. Two corrections of the primary sequence of Aa1 gamma-chains are reported; most of the structural correlates of the alpha-locus allotypes are confirmed. The amino acid sequence of the N-terminal 20 residues of alpha-negative molecules was also determined and found to be homologous to the human VhIII subgroup. These molecules are present in a much higher proportion in the alpha-chain pool than in the gamma-chain.     

Structural determinants of the substrate specificities of xylanases from different glycoside hydrolase families

Xylanases are of widespread importance in several food and non-food biotechnological applications. They degrade heteroxylans, a structurally heterogeneous group of plant cell wall polysaccharides, and other important components in various industrial processes. Because of the highly complex structures of heteroxylans, efficient utilization of xylanases in these processes requires an in-depth knowledge of their substrate specificity. A significant number of studies on the three-dimensional structures of xylanases from different glycoside hydrolase (GH) families in complex with the substrate provided insight into the different mechanisms and strategies by which xylanases bind and hydrolyze structurally different heteroxylans and xylo-oligosaccharides (XOS). Combined with reports on the hydrolytic activities of xylanases on decorated XOS and heteroxylans, major advances have been made in our understanding of the link between the three-dimensional structures and the substrate specificities of these enzymes. In this review, authors gave a concise overview of the structure–function relationship of xylanases from GH5, 8, 10, and 11. The structural basis for inter- and intrafamily variation in xylanase substrate specificity was discussed as are the implications for heteroxylan degradation.