Rearrangement of Retinogeniculate Projection Patterns after Eye-Specific Segregation in Mice

It has been of interest whether and when the rearrangement of neuronal circuits can be induced after projection patterns are formed during development. Earlier studies using cats reported that the rearrangement of retinogeniculate projections could be induced even after eye-specific segregation has occurred, but detailed and quantitative characterization of this rearrangement has been lacking. Here we delineate the structural changes of retinogeniculate projections in the C57BL/6 mouse in response to monocular enucleation (ME) after eye-specific segregation. When ME was performed after eye-specific segregation, rearrangement of retinogeniculate axons in the dorsal lateral geniculate nucleus (dLGN) was observed within 5 days. Although this rearrangement was observed both along the dorsomedial-ventrolateral and outer-inner axes in the dLGN, it occurred more rapidly along the outer-inner axis. We also examined the critical period for this rearrangement and found that the rearrangement became almost absent by the beginning of the critical period for ocular dominance plasticity in the primary visual cortex. Taken together, our findings serve as a framework for the assessment of phenotypes of genetically altered mouse strains as well as provide insights into the mechanisms underlying the rearrangement of retinogeniculate projections.     

The thermal ortho-rearrangement of some carcinogenic N,O-diacetyl-N-arylhydroxylamines.

The half-life times for thermal rearrangement of a series of carcinogenic N, O-diacetyl-N-arylhydroxylamines have been studied. The rate of rearrangement within the series correlates with the extent of aryl conjugation and the degree of electron density in the N-aryl-moiety. Comparison between this rearrangement and the ortho- Claisen rearrangement is drawn and some biological implications of the rearrangement reaction are discussed.     

Flanking Regulatory Sequences of the Tetrahymena R Deletion Element Determine the Boundaries of DNA Rearrangement

In the ciliate Tetrahymena thermophila, thousands of DNA segments of variable size are eliminated from the developing somatic macronucleus by specific DNA rearrangements. It is unclear whether rearrangement of the many different DNA elements occurs via a single mechanism or via multiple rearrangement systems. In this study, we characterized in vivo cis-acting sequences required for the rearrangement of the 1.1-kbp R deletion element. We found that rearrangement requires specific sequences flanking each side of the deletion element. The required sequences on the left side appear to span roughly a 70-bp region that is located at least 30 bp from the rearrangement boundary. When we moved the location of the left cis-acting sequences closer to the eliminated region, we observed a rightward shift of the rearrangement boundary such that the newly formed deletion junction retained its original distance from this flanking region. Likewise, when we moved the flanking region as much as 500 bp away from the deletion element, the rearrangement boundary shifted to remain in relative juxtaposition. Clusters of base substitutions made throughout this critical flanking region did not affect rearrangement efficiency or accuracy, which suggests a complex nature for this regulatory sequence. We also found that the right flanking region effectively replaced the essential sequences identified on the left side, and thus, the two flanking regions contain sequences of analogous function despite the lack of obvious sequence identity. These data taken together indicate that the R-element flanking regions contain sequences that position the rearrangement boundaries from a short distance away. Previously, a 10-bp polypurine tract flanking the M-deletion element was demonstrated to act from a distance to determine its rearrangement boundaries. No apparent sequence similarity exists between the M and R elements. The functional similarity between these different cis-acting sequences of the two elements is firm support for a common mechanism controlling Tetrahymena rearrangement.     

Cutting edge: targeting of V beta to D beta rearrangement by RSSs can be mediated by the V(D)J recombinase in the absence of additional lymphoid-specific factors

Assembly of TCRbeta variable region genes is ordered during thymocyte development with Dbeta to Jbeta rearrangement preceding Vbeta to DJbeta rearrangement. The 5'Dbeta 12-RSS is required to precisely and efficiently target Vbeta rearrangement beyond simply enforcing the 12/23 rule. By prohibiting direct Vbeta to Jbeta rearrangement, this restriction ensures Dbeta gene segment use in the assembly of essentially all TCRbeta variable region genes. In this study, we show that rearrangement of Vbeta 23-RSSs is significantly biased to the Dbeta 12-RSS over Jbeta 12-RSSs on extrachromosomal recombination substrates in nonlymphoid cells that express the recombinase-activating gene-1/2 proteins. These findings demonstrate that targeting of Vbeta to Dbeta rearrangement can be enforced by the V(D)J recombinase in the absence of lymphoid-specific factors other than the recombinase-activating gene-1/2 proteins.     

Models for antigen receptor gene rearrangement. I. Biased receptor editing in B cells: implications for allelic exclusion.

Recent evidence suggests that lymphocyte Ag receptor gene rearrangement does not always stop after the expression of the first productively rearranged receptor. Light chain gene rearrangement in B cells, and alpha-chain rearrangement in T cells can continue, which raises the question: how is allelic exclusion maintained, if at all, in the face of continued rearrangement? In this and the accompanying paper, we present comprehensive models of Ag receptor gene rearrangement and the interaction of this process with clonal selection. Our B cell model enables us to reconcile observations on the kappa:lambda ratio and on kappa allele usage, showing that B cell receptor gene rearrangement must be a highly ordered, rather than a random, process. We show that order is exhibited on three levels: a preference for rearranging kappa rather than lambda light chain genes; a preference to make secondary rearrangements on the allele that has already been rearranged, rather than choosing the location of the next rearrangement at random; and a sequentiality of J segment choice within each kappa allele. This order, combined with the stringency of negative selection, is shown to lead to effective allelic exclusion.     

Analysis of immunoglobulin and T-cell receptor gene rearrangement in cytologic specimens

Recombinant DNA techniques to detect the rearrangement of genes encoding immunoglobulins and T-cell-antigen receptors have been used to identify clonality in lymphoid lesions. To determine the utility of such techniques in cytologic specimens, DNA was analyzed in 24 effusions and 6 fine needle aspirates. Immunophenotypic studies were also performed on the 19 specimens with suspected hematopoietic malignancies. Sufficient material for DNA analysis was present in 28 of the 30 specimens. Immunoglobulin or T-cell-receptor gene rearrangement was present in 13 specimens with atypical cytologic findings; DNA studies provided more information than did the immunologic studies in 3 cases. One T-cell malignancy showed T-cell receptor and heavy-chain gene rearrangement, and one B-cell malignancy showed immunoglobulin and T-cell receptor gene rearrangement. In all patients except one with no evidence of gene rearrangement, the morphologic and immunologic studies also favored a reactive process. Control specimens showed a germline configuration. This study demonstrated that DNA gene rearrangement studies are feasible on many cytologic specimens and may be useful in diagnostically difficult cases.     

Alternate Junctions and Microheterogeneity of Tlr1, a Developmentally Regulated DNA Rearrangement in Tetrahymena thermophila

ABSTRACT. A large number of developmentally regulated DNA rearrangements occur during the development of the macronucleus in Tetrahymena thermophila , Tlr1 is a deletion element which has large inverted repeats near the rearrangement junctions and deletes more than 13 kbp of internal DNA. Previous analysis of caryonidal lines revealed alternate left junctions for the Tlr1 rearrangement in B strain cells. We show here that C2 strain Tetrahymena also use alternate rearrangement junctions. We have mapped and sequenced two additional rearrangement variants and find that both the left and right can vary over a range of approximately 200 bp. We also demonstrate the presence of sequence microheterogeneity in the most commonly found Tlr1 rearrangement product.     

The mechanism of the rearrangement of linoleate hydroperoxides

Linoleate hydroperoxides undergo rearrangement leading to their isomerisation in which the OOH group is relocated or the stereochemistry of a double bond changed, or both. The reaction was studied mainly with pure isomers of methyl hydroperoxylinoleates since conditions could be found in which rearrangement occurred with little accompanying decomposition. The rearrangement was found to be non-stereoselective and took place by a free-radical chain mechanism. Using ¹⁸O-labelled hydroperoxide on ¹⁸O₂, it was shown that the oxygen atoms of the OOH group of the hydroperoxides exchanged with surrounding molecular oxygen during the rearrangement. A mechanism for the rearrangement is proposed.     

Heterogeneity of T-cell beta-chain gene rearrangements in human leukaemias and lymphomas.

The state of T-cell receptor beta-chain gene rearrangement in human T-cell leukaemias has been analysed. All forms of leukaemia tested (T-CLL, ALL, PLL, Sezary syndrome and ATL) exhibit rearrangements of C beta genes confirming the clonality of these neoplasias. However we find no evidence for common gene rearrangements nor for restricted rearrangement patterns within this type of neoplasia. We find evidence of T-cells with C beta 1 and C beta 2 rearrangements, sometimes associated with Igh JH rearrangements, but several cases of T-cell leukaemia with a marker inversion of chromosome 14 (q11;q32) do not have Igh JH rearrangements. The results suggest that TCR beta gene rearrangement occurs early in T-cell ontogeny but that this rearrangement is most often irrelevant to leukaemogenesis.     

Ordered and coordinated rearrangement of the TCR alpha locus: role of secondary rearrangement in thymic selection

The Ag receptor of the T lymphocyte is composed of an alphabeta heterodimer. Both alpha- and beta-chains are products of the somatic rearrangement of V(D)J segments encoded on the respective loci. During T cell development, beta-chain rearrangement precedes alpha-chain rearrangement. The mechanism of allelic exclusion ensures the expression of a single beta-chain in each T cell, whereas a large number of T cells express two functional alpha-chains. Here we demonstrate evidence that TCR alpha rearrangement is initiated by rearranging a 3' Valpha segment and a 5' Jalpha segment on both chromosomes. Rearrangement then proceeds by using upstream Valpha and downstream Jalpha segments until it is terminated by successful positive selection. This ordered and coordinated rearrangement allows a single thymocyte to sequentially express multiple TCRs with different specificities to optimize the efficiency of positive selection. Thus, the lack of allelic exclusion and TCR alpha secondary rearrangement play a key role in the formation of a functional T cell repertoire.     

The requirement for pre-TCR during thymic differentiation enforces a developmental pause that is essential for V-DJβ rearrangement

T cell development occurs in the thymus and is critically dependent on productive TCRβ rearrangement and pre-TCR expression in DN3 cells. The requirement for pre-TCR expression results in the arrest of thymocytes at the DN3 stage (β checkpoint), which is uniquely permissive for V-DJβ recombination; only cells expressing pre-TCR survive and develop beyond the DN3 stage. In addition, the requirement for TCRβ rearrangement and pre-TCR expression enforces suppression of TCRβ rearrangement on a second allele, allelic exclusion, thus ensuring that each T cell expresses only a single TCRβ product. However, it is not known whether pre-TCR expression is essential for allelic exclusion or alternatively if allelic exclusion is enforced by developmental changes that can occur in the absence of pre-TCR. We asked if thymocytes that were differentiated without pre-TCR expression, and therefore without pause at the β checkpoint, would suppress all V-DJβ rearrangement. We previously reported that premature CD28 signaling in murine CD4(-)CD8(-) (DN) thymocytes supports differentiation of CD4(+)CD8(+) (DP) cells in the absence of pre-TCR expression. The present study uses this model to define requirements for TCRβ rearrangement and allelic exclusion. We demonstrate that if cells exit the DN3 developmental stage before TCRβ rearrangement occurs, V-DJβ rearrangement never occurs, even in DP cells that are permissive for D-Jβ and TCRα rearrangement. These results demonstrate that pre-TCR expression is not essential for thymic differentiation to DP cells or for V-DJβ suppression. However, the requirement for pre-TCR signals and the exclusion of alternative stimuli such as CD28 enforce a developmental "pause" in early DN3 cells that is essential for productive TCRβ rearrangement to occur.     

Models for antigen receptor gene rearrangement. II. Multiple rearrangement in the TCR: allelic exclusion or inclusion?

This series of papers addresses the effects of continuous Ag receptor gene rearrangement in lymphocytes on allelic exclusion. The previous paper discussed light chain gene rearrangement and receptor editing in B cells, and showed that these processes are ordered on three different levels. This order, combined with the constraints imposed by a strong negative selection, was shown to lead to effective allelic exclusion. In the present paper, we discuss rearrangement of TCR genes. In the TCR alpha-chain, allelic inclusion may be the rule rather than the exception. Several previous models, which attempted to explain experimental observations, such as the fractions of cells containing two productive TCRalpha rearrangements, did not sufficiently account for TCR gene organization, which limits secondary rearrangement, and for the effects of subsequent thymic selection. We present here a detailed, comprehensive computer simulation of TCR gene rearrangement, incorporating the interaction of this process with other aspects of lymphocyte development, including cell division, selection, cell death, and maturation. Our model shows how the observed fraction of T cells containing productive TCRalpha rearrangements on both alleles can be explained by the parameters of thymic selection imposed over a random rearrangement process.     

TCR基因重排在蕈样肉芽肿诊断中的应用

T细胞在成熟过程中通过T细胞表面受体基因重排,从而具有特异性识别抗原的能力,在这一过程中的任何失调都会导致疾病。蕈样肉芽肿是由于淋巴细胞的恶性增殖所导致的,病变组织表现出T细胞受体基因重排克隆性。通过Southern印迹分析技术和PCR技术来检测T细胞受体基因重排。T细胞受体基因重排的检测在蕈样肉芽肿的诊断的应用上有重要的参考价值。     

Cloning of an activated human ret gene with a novel 5' sequence fused by DNA rearrangement.

By transfecting a high-Mr DNA from human stomach cancer into NIH3T3 cells, a transforming sequence that showed homology with the human ret gene was identified. The transforming sequence was found to be generated by a DNA rearrangement in the human ret proto-oncogene. This rearrangement was suggested to have occurred during the transfection procedure. The nucleotide sequences of cDNAs of the rearranged ret gene and deduced amino acid (aa) sequences revealed that the rearrangement had resulted in recombination of the 3' segment of the ret proto-oncogene with a segment of an unknown human sequence, and that the recombination had generated a novel gene encoding a fusion protein of 435 aa. The rearrangement was presumed to be responsible for activation of the ret gene.     

Microangiographic signs of blood vessel rearrangement during tumor growth

In the experiment performed in mice with a subcutaneously implanted sarcoma-37 on the chin, rearrangement of the blood vessels has been followed by means of micro-roentgenography. In the process of the implanted tumour growth, the blood vessels undergo a profound functional-anatomical rearrangement, which develops, beginning from the first hours, in two ways: at the expense of the peripheral vessels rearrangement in the recepient and at the expense of real tumorous vessels development ensuaring vascular trophic of the tumour.