Nobuyuki Kurosawa

Rapid production of antigen-specific monoclonal antibodies from a variety of animals

BackgroundAlthough a variety of animals have been used to produce polyclonal antibodies against antigens, the production of antigen-specific monoclonal antibodies from animals remains challenging.ResultsWe propose a simple and rapid strategy to produce monoclonal antibodies from a variety of animals. By staining lymph node cells with an antibody against immunoglobulin and a fluorescent dye specific for the endoplasmic reticulum, plasma/plasmablast cells were identified without using a series of antibodies against lineage markers. By using a fluorescently labeled antigen as a tag for a complementary cell surface immunoglobulin, antigen-specific plasma/plasmablast cells were sorted from the rest of the cell population by fluorescence-activated cell sorting. Amplification of cognate pairs of immunoglobulin heavy and light chain genes followed by DNA transfection into 293FT cells resulted in the highly efficient production of antigen-specific monoclonal antibodies from a variety of immunized animals.ConclusionsOur technology eliminates the need for both cell propagation and screening processes, offering a significant advantage over hybridoma and display strategies.

Reduced level of the BCL11B protein is associated with adult T-cell leukemia/lymphoma.

Background Adult T-cell leukemia/lymphoma (ATLL) develops in a small proportion of human T-cell leukemia virus type I (HTLV-I)-infected individuals. However, the mechanism by which HTLV-I causes ATLL has not been fully elucidated. To provide fundamental insights into the multistep process of leukemogenesis, we have mapped the chromosomal abnormalities in 50 ATLL cases to identify potential key regulators of ATLL. Results The analysis of breakpoints in one ATLL case with the translocations t(14;17)(q32;q22-23) resulted in the identification of a Kruppel zinc finger gene, BCL11B, which plays a crucial role in T-cell development. Among the 7 ATLL cases that we examined by immunofluorescence analysis, 4 displayed low and one displayed moderate BCL11B signal intensities. A dramatically reduced level of the BCL11B protein was also found in HTLV-I-positive T-cell lines. The ectopic expression of BCL11B resulted in significant growth suppression in ATLL-derived cell lines but not in Jurkat cells. Conclusions Our genetic and functional data provide the first evidence that a reduction in the level of the BCL11B protein is a key event in the multistep progression of ATLL leukemogenesis.

Target-selective homologous recombination cloning for high-throughput generation of monoclonal antibodies from single plasma cells

BackgroundMolecular cloning of functional immunoglobulin genes from single plasma cells is one of the most promising technologies for the rapid development of monoclonal antibody drugs. However, the proper insertion of PCR-amplified immunoglobulin genes into expression vectors remains an obstacle to the high-throughput production of recombinant monoclonal antibodies.ResultsWe developed a single-step cloning method, target-selective homologous recombination (TS-HR), in which PCR-amplified immunoglobulin variable genes were selectively inserted into vectors, even in the presence of nonspecifically amplified DNA. TS-HR utilizes Red/ET-mediated homologous recombination with a target-selective vector (TS-vector) with unique homology arms on its termini. Using TS-HR, immunoglobulin variable genes were cloned directly into expression vectors by co-transforming unpurified PCR products and the TS-vector into E. coli. Furthermore, the high cloning specificity of TS-HR allowed plasmids to be extracted from pools of transformed bacteria without screening single colonies for correct clones. We present a one-week protocol for the production of recombinant mouse monoclonal antibodies from large numbers of single plasma cells.ConclusionThe time requirements and limitations of traditional cloning procedures for the production of recombinant immunoglobulins have been significantly reduced with the development of the TS-HR cloning technique.

TCR variable gene involvement in chromosome inversion between 14q11 and 14q24 in adult T-cell leukemia

AbstractChromosomal translocations in T-cell malignancies frequently involve the T-cell receptor (TCR)α/δ locus at chromosome 14q11. Although 14q11 abnormalities are found in about 10% of adult T-cell leukemia (ATL) cases, until now there has been no direct evidence showing involvement of the TCR locus in ATL—a malignancy closely associated with HTLV-1 infection. The breakpoints of T-cell malignancies most commonly occur within the Jα or Jδ region of the TCR locus. In ATL, however, despite extensive searching no breakpoint has yet been found in that region. Using fluorescence in situ hybridization with a panel of cosmid and bacterial artificial chromosome probes derived from chromosome 14, including the variable region of the TCRα locus, comprehensive analysis of an ATL patient carrying inv(14)(q11q32) revealed that the TCR locus was indeed involved in this inversion. Molecular cloning of the breakpoint revealed the juxtaposition of TCR Vα to the 14q24 region as a result of two consecutive inversions: inv(14)(q11q32) and inv(14)(q11q24). We also found a gene near the breakpoint at the 14q24 region that is downregulated in this ATL patient and is assigned in the database as a pseudogene of ADAM21 (a disintegrin and metalloproteinase domain 21). Our expression analysis, however, showed that this pseudogene was actually expressed and was capable of encoding a protein similar to ADAM21; thus we have named this gene ADAM21-like (ADAM21-L).

Molecular characterization of a novel translocation t(5;14)(q21;q32) in a patient with congenital abnormalities

AbstractChromosomal translocations are frequently found to be associated with various malignant disorders as well as congenital abnormalities. We report the characterization of a novel reciprocal translocation t(5;14)(q21;q32) in a patient with congenital abnormalities manifested by severe mental retardation, athetotic tetraplegia, microcephaly, peculiar facies (upward slanting of palpebral fissures), clinodactyly of the fifth fingers, and overlapping toes. Using a JHGP24 lymphoblast cell line derived from this patient, metaphase fluorescence in situ hybridization with bacterial artificial chromosome and cosmid probes and subsequent molecular analysis mapped the translocation breakpoint to the nucleotide level. Sequence analysis of the breakpoint junctions revealed the presence of a homologous sequence, GTGGC, along with a single nucleotide substitution and an insertion in der(14), and a single nucleotide deletion in the der(5) chromosome. We also attempted to identify and characterize the transcripts near the breakpoint by 5′ and 3′ rapid amplification of cDNA ends. Although we found several transcripts near the breakpoint of chromosome 14, the lack of significant ORFs within these transcripts suggests they are likely to be non-coding RNAs. These transcripts may have an important role in the neurogenesis or differentiation.

Novel method for the high-throughput production of phosphorylation site-specific monoclonal antibodies

Threonine phosphorylation accounts for 10% of all phosphorylation sites compared with 0.05% for tyrosine and 90% for serine. Although monoclonal antibody generation for phospho-serine and -tyrosine proteins is progressing, there has been limited success regarding the production of monoclonal antibodies against phospho-threonine proteins. We developed a novel strategy for generating phosphorylation site-specific monoclonal antibodies by cloning immunoglobulin genes from single plasma cells that were fixed, intracellularly stained with fluorescently labeled peptides and sorted without causing RNA degradation. Our high-throughput fluorescence activated cell sorting-based strategy, which targets abundant intracellular immunoglobulin as a tag for fluorescently labeled antigens, greatly increases the sensitivity and specificity of antigen-specific plasma cell isolation, enabling the high-efficiency production of monoclonal antibodies with desired antigen specificity. This approach yielded yet-undescribed guinea pig monoclonal antibodies against threonine 18-phosphorylated p53 and threonine 68-phosphorylated CHK2 with high affinity and specificity. Our method has the potential to allow the generation of monoclonal antibodies against a variety of phosphorylated proteins.

Minimum length of homology arms required for effective Red/ET recombination.

The original protocol of Red/ET recombination requires 50-bp sequence homology with target vector on both sides of the DNA fragment. To make it more cost effective, we investigated to determine the minimal length of homology required for the system to work. We found that a homology of 9-bp was sufficient to achieve homologous recombination with more than 50% efficiency.

Quantitative trait loci for age-related memory dysfunction in SAMP8 and JF1 mice

Abstract The senescence-accelerated mouse (SAM) P8 strain exhibits severe age-related learning and memory deficits (LMD) well before the median age of survival. As a first step to clarify the genes involved in this deterioration, we have performed genetic analysis of SAMP8 using the whole genome scan for quantitative trait loci (QTLs) specifying the impairment in step-through passive avoidance response with F2 intercrosses of SAMP8 exhibiting short retention time (RT) and Japanese Fancy Mouse 1 (JF1) derived from Japanese wild mouse ( Mus musculus molossinus ) exhibiting normal long retention time. Genetic markers were typed at 113 loci spanning all chromosomes except the Y. Five loci have been identified with significant linkage to chromosomes 1, 12, 13 and 15 by interval mapping of 264 F2 mice. Three of them on chromosomes 1, 12, and 13 are due to SAMP8 background, while two of them on chromosome 15 are derived from JF1 background despite parental JF1 strain shows normal phenotype.

Possible involvement of Hcn1 ion channel in learning and memory dysfunction in SAMP8 mice.

The senescence-accelerated mouse prone 8 (SAMP8) strain exhibits age-related learning and memory deficits (LMD) at 2 months of age. Combined linkage analysis of 264 F2 intercross SAMP8 × JF1 mice and RNA-seq analysis identified Hcn1 gene out of 29 genes in the LMD region on chromosome 13. Hcn1 in SAMP8 strain showed 15 times less polyglutamine repetition compared to Japanese fancy mouse 1 (JF1). Whole cell patch clamp analysis showed that Hcn1 ion conductivity was significantly lower in SAMP8 compared to that of JF1, which may be associated with learning and memory deficiency.