scholarly journals GENETIC CONTROL OF THE ANTIBODY RESPONSE IN INBRED MICE

1968 ◽  
Vol 128 (1) ◽  
pp. 1-11 ◽  
Author(s):  
Hugh O. McDevitt ◽  
Marvin L. Tyan
Keyword(s):  
Genetic Control ◽  
Antibody Formation ◽  
Inbred Mice ◽  
Progeny Testing ◽  
Secondary Immune Response ◽  
Linkage Studies ◽  
Spleen Cells ◽  
The Third ◽  
Backcross Populations ◽  
Synthetic Polypeptide

The transfer of spleen cells from (C3H x C57Bl/6) F1 mice, capable of responding to (T,G)-A--L, into irradiated C3H parental recipients, normally incapable of responding to (T,G)-A--L, transfers the ability to make either a primary or secondary immune response to this synthetic polypeptide antigen. This localizes the genetic control of the ability to respond to the spleen cell population and indicates that the genetic control is exerted upon a process directly related to antibody formation. Studies with congenic strains of mice and linkage studies in segregating backcross populations show that the ability to respond to (T,G)-A--L and (H,G)-A--L is linked to the H-2 locus and can thus be localized to the IXth mouse linkage group. Note Added in Proof: Of the three possible recombinant animals noted in Tables IV and V, two were infertile. The third animal was not a recombinant, since progeny testing and reimmunization showed that this animal was an H-22/H-2k heterozygote capable of responding well to (T,G)-A--L.

scholarly journals CELLULAR BASIS OF THE GENETIC CONTROL OF IMMUNE RESPONSES TO SYNTHETIC POLYPEPTIDES

1970 ◽  
Vol 132 (4) ◽  
pp. 613-622 ◽  
Author(s):  
Edna Mozes ◽  
G. M. Shearer ◽  
Michael Sela
Keyword(s):  
Immune Response ◽  
Genetic Control ◽  
Relative Number ◽  
Precursor Cells ◽  
Spleen Cells ◽  
Low Responders ◽  
Synthetic Polypeptides ◽  
Low Responder ◽  
Synthetic Polypeptide ◽  
High Responders

SJL mice are high responders to the synthetic multichain polypeptide antigen (T,G)-Pro--L, whereas DBA/1 mice are low responders (10, 11). In order to determine whether the genetic control of immune response can be correlated with the number of antigen-sensitive precursor cells, spleen cell suspensions from normal and immunized SJL and DBA/1 donor mice were transplanted into lethally X-irradiated syngeneic recipients (incapable of immune response) along with (T, G)-Pro--L. Anti-(T, G)-Pro--L responses (donor-derived) were assayed in the sera of the hosts 12–16 days later. By transplanting graded and limiting numbers of spleen cells, inocula were found which contained one or a few antigen-sensitive precursors reactive with the immunogen. Using this method to estimate the relative numbers of such cells for the high responder SJL strain, one precursor was detected in ∼1.3 x 106 and ∼7.2 x 106 spleen cells from immunized and normal donors, respectively. In contrast, one precursor was detected in about 30 x 106 spleen cells from low responder DBA/1 mice, irrespective of whether the donors had been immunized. These results indicate that the genetic control of immunity to the synthetic polypeptide antigen investigated is directly correlated to the relative number of precursor cells reactive with the immunogen in high and low responder strains.

scholarly journals GENETIC CONTROL OF THE IMMUNE RESPONSE

1972 ◽  
Vol 135 (6) ◽  
pp. 1259-1278 ◽  
Author(s):  
Hugh O. McDevitt ◽  
Beverly D. Deak ◽  
Donald C. Shreffler ◽  
Jan Klein ◽  
Jack H. Stimpfling ◽  
...  
Keyword(s):  
Immune Response ◽  
Genetic Control ◽  
Linkage Test ◽  
Progeny Testing ◽  
Crossover Event ◽  
Extensive Analysis ◽  
Synthetic Polypeptides ◽  
Synthetic Polypeptide

Eleven strains of mice bearing recombinant H-2 chromosomes derived from known crossover events between known H-2 types were immunized with a series of branched, multichain, synthetic polypeptide antigens [(T,G)-A--L, (H,G)-A--L, and (Phe,G)-A--L]. Results with nine of the eleven H-2 recombinants indicated that the gene(s) controlling immune response to these synthetic polypeptides (Ir-1) is on the centromeric or H-2K part of the recombinant H-2 chromosome. Results with two of the eleven recombinant H-2 chromosomes indicated that Ir-1 was on the telomeric or H-2D part of the recombinant H-2 chromosome. Both of these recombinants were derived from crossovers between the H-2K locus and the Ss-Slp locus near the center of the H-2 region. One of these recombinants, H-2y, was derived from a known single crossover event. These results indicate that Ir-1 lies near the center of the H-2 region between the H-2K locus and the Ss-Slp locus. The results of a four-point linkage test were consistent with these results. In 484 offspring of a cross designed to detect recombinants between H-2 and Ir-1, only two putative recombinants were detected. Both of these recombinants were confirmed by progeny testing. Extensive analysis of one of them has shown that the crossover event occurred within the H-2 region. (Testing of the second recombinant is currently under way.) Thus, in the linkage test, recombinants between H-2 and Ir-1 are in fact intra-H-2 crossovers. These results permit assignment of Ir-1 to a position between the H-2K locus and the Ss-Slp locus.

scholarly journals CELLULAR BASIS OF THE GENETIC CONTROL OF IMMUNE RESPONSES TO SYNTHETIC POLYPEPTIDES

1971 ◽  
Vol 133 (2) ◽  
pp. 216-230 ◽  
Author(s):  
G. M. Shearer ◽  
Edna Mozes ◽  
Michael Sela
Keyword(s):  
Genetic Control ◽  
Inbred Mouse ◽  
Phenotypic Expression ◽  
Mouse Strains ◽  
Spleen Cells ◽  
Chi Square ◽  
Synthetic Polypeptides ◽  
Chi Square Test ◽  
Synthetic Polypeptide ◽  
Syngeneic Recipient

DBA/1 mice are high responders to the (Phe, G) determinant of the synthetic polypeptide (Phe, G)-Pro--L, whereas SJL mice respond well to the Pro--L region of this macromolecule (6). In order to determine whether the phenomenon described above is related to the number of antigen-sensitive units detected for both specificities, and whether responses to these determinants can be transferred independently, graded and limiting inocula of spleen cells from SJL, DBA/1, and F1 donors were injected into X-irradiated, syngeneic, recipient mice with (Phe, G)-Pro--L. By this approach, one antigen-sensitive unit specific for (Phe, G) was detected in 1.7 x 106 and 8.5 x 106 spleen cells from immunized and nonimmunized DBA/1 donors, respectively. In contrast, one (Phe, G) relevant precursor was detected in 20 x 106 SJL spleen cells, irrespective of whether the donors had been immunized. On the other hand, for the Pro--L specificity, one limiting splenic precursor was found in 1.3 x 106 and in 3.4 x 106 cells for immunized and nonimmunized SJL donors, respectively; whereas one response unit was estimated for this determinant in 9.4 x 106 and in 38 x 106 spleen cells from immunized and nonimmunized DBA/1 mice. The findings reported here indicate that the phenotypic expression of the genetic control(s) for immune responsiveness to different immunopotent regions of (Phe, G)-Pro--L is directly correlated with the number of immunocompetent response units detected in two inbred mouse strains. In the spleens of immunized F1 donors, similar frequencies of one limiting precursor in 3.0 x 106 and in 2.8 x 106 cells were detected for (Phe, G) and Pro--L, respectively. The results of a chi-square test for independence of (Phe, G) and Pro--L responses in F1 animals is compatible with the hypothesis that the transferred spleen cells limiting the response to (Phe, G)-Pro--L are restricted to generate antibodies specific for only one of the two determinants of this macromolecule.

scholarly journals Genetic Control of the Radiosensitivity of Lymphoid Cells for Antibody Formation Ability in Mice.

1994 ◽  
Vol 35 (3) ◽  
pp. 179-185
Author(s):  
MASAAKI OKUMOTO ◽  
NOBUKO MORI ◽  
SHUNSUKE IMAI ◽  
SATOMI HAGA ◽  
JO HILGERS ◽  
...  
Keyword(s):  
Genetic Control ◽  
Antibody Formation ◽  
Lymphoid Cells

The genetic control of the distinction between fat body and gonadal mesoderm in Drosophila

Development ◽  
1998 ◽  
Vol 125 (4) ◽  
pp. 713-723 ◽  
Author(s):  
V. Riechmann ◽  
K.P. Rehorn ◽  
R. Reuter ◽  
M. Leptin
Keyword(s):  
Genetic Control ◽  
Early Development ◽  
Fat Body ◽  
Homeotic Gene ◽  
Dorsoventral Patterning ◽  
Genetic Pathways ◽  
The Third ◽  
Body Development ◽  
Visceral Muscles ◽  
Somatic Muscles

The somatic muscles, the heart, the fat body, the somatic part of the gonad and most of the visceral muscles are derived from a series of segmentally repeated primordia in the Drosophila mesoderm. This work describes the early development of the fat body and its relationship to the gonadal mesoderm, as well as the genetic control of the development of these tissues. Segmentation and dorsoventral patterning genes define three regions in each parasegment in which fat body precursors can develop. Fat body progenitors in these regions are specified by different genetic pathways. Two regions require engrailed and hedgehog for their development while the third is controlled by wingless. decapentaplegic and one or more unknown genes determine the dorsoventral extent of these regions. In each of parasegments 10–12 one of these regions generates somatic gonadal precursors instead of fat body. The balance between fat body and somatic gonadal fate in these serially homologous cell clusters is controlled by at least five genes. We suggest a model in which tinman, engrailed and wingless are necessary to permit somatic gonadal develoment, while serpent counteracts the effects of these genes and promotes fat body development. The homeotic gene abdominalA limits the region of serpent activity by interfering in a mutually repressive feed back loop between gonadal and fat body development.

Inheritance of siliqua strength in Brassica campestris L. I. Studies of F2 and backcross populations

1986 ◽  
Vol 28 (3) ◽  
pp. 365-373 ◽  
Author(s):  
G. P. Kadkol ◽  
G. M. Halloran ◽  
R. H. Macmillan
Keyword(s):  
Epistatic Interaction ◽  
Brassica Campestris ◽  
The Third ◽  
Backcross Populations ◽  
Siliqua Strength ◽  
Brown Sarson

The inheritance of siliqua strength was studied in Brassica campestris L. using F1, F2, and backcross generations of crosses between cv. Torch (shatter susceptible) and var. Yellow Sarson and var. Brown Sarson (shatter resistant) accessions. Shatter resistance (high siliqua strength) was recessive in all crosses. Crosses involving DS-17-D (var. Brown Sarson) indicated that siliqua strength is most likely controlled by two genes that show dominant epistatic interaction. Crosses of IB-5 and B-46 (both var. Yellow Sarson) each with cv. Torch indicated the likelihood of three genes controlling siliqua strength, two of which appeared to be epistatic over the third gene when dominant. In these crosses, the multivalve character appeared to be controlled by three genes, two of which were epistatic over the third gene resulting in multivalve character when the former two were recessive. Segregation for siliqua strength in the var. Yellow Sarson crosses was not independent of segregation for multivalve character.Key words: Brassica, siliqua strength, shatter resistance, Sarson.

Clues from other animals and theoretical considerations

Development ◽  
1987 ◽  
Vol 101 (Supplement) ◽  
pp. 3-4
Author(s):  
Anne McLaren
Keyword(s):  
Sex Determination ◽  
Genetic Control ◽  
Y Chromosome ◽  
X Chromosome ◽  
X Chromosomes ◽  
The Third ◽  
Mouse Species ◽  
Primary Male ◽  
Theoretical Considerations ◽  
State Of Activity

In the first two papers of this volume, the genetic control of sex determination in Caenorhabditis and Drosophila is reviewed by Hodgkin and by Nöthiger & Steinmarin-Zwicky, respectively. Sex determination in both cases depends on the ratio of X chromosomes to autosomes, which acts as a signal to a cascade of règulatory genes located either on autosomes or on the X chromosome. The state of activity of the last gene in the sequence determines phenotypic sex. In the third paper, Erickson & Tres describe the structure of the mouse Y chromosome and the polymorphisms that have been detected in different mouse species and strains. As in all mammals, the Y carries the primary male-determining locus; autosomal genes may also be involved in sex determination, but they must act down-stream from the Y-linked locus.

The genetic control of antibody formation

1983 ◽  
Vol 4 (1-2) ◽  
pp. 3-42
Author(s):  
Rochelle K. Seide ◽  
J. Michael Kehoe
Keyword(s):  
Genetic Control ◽  
Antibody Formation

Genetic control of T-Cell subset representation in inbred mice

1983 ◽  
Vol 18 (6) ◽  
pp. 585-592 ◽  
Author(s):  
Georg Kraal ◽  
Irving L. Weissman ◽  
Eugene C. Butcher
Keyword(s):  
T Cell ◽  
Genetic Control ◽  
Inbred Mice ◽  
Cell Subset ◽  
T Cell Subset

scholarly journals GENETIC CONTROL OF THE ANTIBODY RESPONSE

1967 ◽  
Vol 126 (5) ◽  
pp. 969-978 ◽  
Author(s):  
Hugh O. McDevitt ◽  
Michael Sela
Keyword(s):  
Immune Response ◽  
Antibody Response ◽  
Glutamic Acid ◽  
Genetic Control ◽  
Antigenic Determinants ◽  
Polyglutamic Acid ◽  
Cross Reactions ◽  
Cba Mice ◽  
Related Series ◽  
Synthetic Polypeptide

CBA and C57 mice were tested for their ability to make an immune response to a related series of branched, multichain synthetic polypeptide antigens in which the antigenic determinants on the amino termini of the branched side chains were systematically varied. Neither strain responded to the polyglutamic acid determinant. Both strains responded well and equally to the poly(phenylalanine, glutamic acid) determinants. CBA mice responded poorly, and C57 mice responded well to two different antigens bearing poly(tyrosine, glutamic acid) determinants. CBA mice responded well, and CS7 mice responded poorly to two different antigens bearing poly(histidine, glutamic acid) determinants. The genetic control of the immune response to (H,G)-A--L appears to be dominant and polygenic, as it has been shown to be for (T,G)-A--L. The related antigens used in this study show extensive cross-reactions with antisera against other members of the related series.

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