Erik Timmers scite author profile

Twenty-one independent immunoglobulin heavy chain VH3DJH rearrangements were cloned and sequenced from livers of human fetuses at 7, 13 and 18 weeks of gestation. The VH elements expressed were not somatically mutated. Eight out of the estimated 30 VH3 elements were utilized with a preference for five of them. One of these VH3 sequences, designated FL13-28, represented a thus-far unknown VH3 gene segment. From the six functional JH elements the JH3 and JH4 segments were utilized preferentially and from the estimated 30 D segments the DQ52 element and the Dxp family were found to rearrange frequently. D elements were utilized both in normal and inverted orientation, as single copies or in D to D fusions. Addition of N nucleotides, removal of nucleotides from the coding sequences and utilization of DIR elements (D genes with irregular recombination signals) further expanded the third complementarity-determining region (CDR3) diversity. One fourth of the fetal CDR3 regions lacked N regions. Due to utilization of DQ52, the relative absence of N regions and extensive exonuclease activity operating on the D elements, the fetal CDR3 regions were significantly shorter than those found in adult B lymphocytes.

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DNA sequences at the ends of the genome of bacteriophage Mu essential for transposition.

Groenen¹,

Timmers²,

Putte³

1985

Proc. Natl. Acad. Sci. U.S.A.

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We have determined the minimal DNA sequences at the ends of the genome of bacteriophage Mu that are required for its transposition. A mini-Mu was constructed on a multicopy plasmid that enabled the manipulation of the DNA sequences at its ends without affecting the genes essential for transposition. The genes A and B, which were cloned outside the ends of the mini-Mu on the same plasmid, were both needed for optimal transposition. In our experimental system the predominant end products of the transposition are cointegrates both in the presence and in the absence of B. Two regions ending approximately 25 and 160 bp from the left end and one ending approximately 50 bp from the right end appear to be essential for optimal transposition. Overlapping with these regions, a 22-base-pair sequence was recognized with the consensus Y -G-T-T-T-C-A-Y-T-N-N-A-A-R-Y-R-C-G-A-A-A-A, where Y and R represent any pyrimidine and purine, respectively. At the left end these sequences occur as direct repeats; at the right end this sequence is inverted with respect to those at the left end.Bacteriophage Mu is a very efficient transposon as it replicates by an active process of transposition (for a recent review, see ref. 1). Two phage-coded proteins A and B (2, 3) are essential for this process. A is absolutely required, whereas in the absence of B there is a decrease of the transposition frequency by a factor of 100 (4, 5). Other phagecoded functions-e.g., ner (6), arm (7), and kil, gam, lig, or sot (8)-are involved in modulating the efficiency of transposition. Typically the nucleotide sequences at the ends of most transposons are more or less perfect inverted repeats varying between approximately 18 and 40 base pairs (bp) (9,10). The terminal inverted repeats of bacteriophage Mu, however, are only 2 bp in length. It was shown (11) that there is an essential Mu sequence required for transposition between nucleotides 27 and 116 from the right end. Examination of the sequences near the left end (12, 13) and right end (14, 15) reveals considerable stretches of homology in both inverted and direct orientation (Fig. 1). To investigate the importance of these sequences we have determined the sequences at the ends of the genome of Mu that are minimally required for transposition. To this purpose a mini-Mu was constructed that allowed the digestion of DNA sequences by exonuclease BAL-31 from within the mini-Mu towards the ends without affecting the genes essential for transposition.These genes were cloned under the control of a strong inducible promoter on the same plasmid but separated from the mini-Mu. By using this system A and B are still provided in cis, which might be important for optimal transposition.

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X-linked agammaglobulinemia

Timmers

Weers

Alt

et al. 1991

Clinical Immunology and Immunopathology

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Immunoglobulin x light chain germ‐line transcripts in human precursor B lymphocytes

Thompson¹,

Timmers²,

Kenter³

et al. 1992

Eur J Immunol

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B lymphoblastoid cell lines (BLCL), established from bone marrow and peripheral blood mononuclear cells from two severe combined immunodeficiency (SCID) patients, manifested a complete absence of genomic rearrangements of the immunoglobulin (Ig) heavy (H) and light (L) chain loci. The BLCL contained germ-line transcripts of the Ig kappa region locus of approximately 1.2 kilobase (kb). By cDNA cloning and sequence analysis the transcripts were shown to consist of a C kappa segment, a J kappa 1 gene segment, 160 base pairs (bp) of J kappa 1 5' intervening sequence, containing the heptamer/nonamer recombination recognition sequences and at the 5' end a 523-bp segment designated human kappa zero, The first 206 bp of this 5' segment were homologous to the reported murine kappa zero region. Genomic restriction mapping and DNA sequence analysis demonstrated that the human kappa zero segment is located approximately 4 kb upstream of J kappa 1. The kappa zero segment contains a putative promoter region with an OCT2 binding site, and has a splice donor site to accomplish splicing to an acceptor site 160 bp upstream of J kappa 1. Expression of the kappa zero gene segment was found in BLCL derived from normal fetal bone marrow, in which both Ig kappa loci were in the germ-line configuration. These findings indicate that the described transcripts are not only present in SCID, but also in normal developing pre-B lymphocytes. The expression of germ-line Ig kappa L chain transcripts may be associated with the locus becoming accessible to gene rearrangement.

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Diversity of immunoglobulin heavy chain gene segment rearrangement in B lymphoblastoid cell lines from X‐linked agammaglobulinemia patients

et al. 1991

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X-linked agammaglobulinemia (XLA) is characterized by an arrest in early B lymphocyte differentiation. Precursor B cells are present in the bone marrow (BM), whereas peripheral blood B cell numbers are severely decreased. A series of Epstein-Barr virus (EBV)-transformed B lymphoblastoid cell lines (BLCL) was established from peripheral blood of three XLA patients belonging to one pedigree. These BLCL manifested productive VHDJH rearrangements and a random utilization of the VH families. The CDR3 regions of the rearrangements varied in length from 12 to 47 nucleotides and included N regions in all cases. The results supported the conclusion that the few B lymphocytes in peripheral blood of XLA patients exhibit all mechanisms that generate immunoglobulin (Ig) heavy (H) chain diversity. However, no evidence for somatic mutation was found. Within the VH3 family 50% of the expressed VH gene segments belonged to a single subgroup and within the VH4 family a preferential utilization of one VH4 gene element was observed. The utilization of H chain joining (HH) elements was biased to JH4 and JH6 and a high percentage of the CDR3 regions was found to be generated by unconventional mechanisms, such as multiple D usage and the fusion of D elements to D segments with irregular recombination recognition signals. These unique features of the recombined and expressed VHDJH regions in XLA may explain the inability of XLA patients to respond to a variety of antigens. Alternatively, they could be secondary to a B lymphocyte maturation defect in XLA.

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Erik Timmers

Restricted utilization of germ‐line V_H3 genes and short diverse third complementarity‐determining regions (CDR3) in human fetal B lymphocyte immunoglobulin heavy chain rearrangements

DNA sequences at the ends of the genome of bacteriophage Mu essential for transposition.

X-linked agammaglobulinemia

Immunoglobulin x light chain germ‐line transcripts in human precursor B lymphocytes

Diversity of immunoglobulin heavy chain gene segment rearrangement in B lymphoblastoid cell lines from X‐linked agammaglobulinemia patients

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About

Erik Timmers

Restricted utilization of germ‐line VH3 genes and short diverse third complementarity‐determining regions (CDR3) in human fetal B lymphocyte immunoglobulin heavy chain rearrangements

DNA sequences at the ends of the genome of bacteriophage Mu essential for transposition.

X-linked agammaglobulinemia

Immunoglobulin x light chain germ‐line transcripts in human precursor B lymphocytes

Diversity of immunoglobulin heavy chain gene segment rearrangement in B lymphoblastoid cell lines from X‐linked agammaglobulinemia patients

Contact Info

Product

Resources

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Restricted utilization of germ‐line V_H3 genes and short diverse third complementarity‐determining regions (CDR3) in human fetal B lymphocyte immunoglobulin heavy chain rearrangements