Single nucleotide polymorphic sites of the bovine MAP1B, PPP1R11, and DDX4 genes are associated with improved bull fertility as measured by e.g. sire conception rates. Nucleic acid molecules, arrays, kits, methods of genotyping and marker-assisted bovine breeding methods based on these SNPs are disclosed.

Non-human animals comprising a human or humanized IL-4 and/or IL-4Rα nucleic acid sequence are provided. Non-human animals that comprise a replacement of the endogenous IL-4 gene and/or IL-4Rα gene with a human IL-4 gene and/or IL-4Rα gene in whole or in part, and methods for making and using the non-human animals, are described. Non-human animals comprising a human or humanized IL-4 gene under control of non-human IL-4 regulatory elements is also provided, including non-human animals that have a replacement of non-human IL-4-encoding sequence with human IL-4-encoding sequence at an endogenous non-human IL-4 locus. Non-human animals comprising a human or humanized IL-4Rα gene under control of non-human IL-4Rα regulatory elements is also provided, including non-human animals that have a replacement of non-human IL-4Rα-encoding sequence with human or humanized IL-4Rα-encoding sequence at an endogenous non-human C IL-4Rα locus. Non-human animals comprising human or humanized IL-4 gene and/or IL-4Rα sequences, wherein the non-human animals are rodents, e.g., mice or rats, are provided.

The present invention relates to modulators of FAS and DRs and their method of use in the treatment and prevention of diseases and pathologies related to accumulation of senescent cells during aging, such as cancer, chronic obstructive pulmonary disease (COPD), osteoarthritis, atherosclerosis, neurodegenerative diseases, diabetes, and many others. The present invention also relates to pharmaceutical compositions containing these compounds as well as various uses thereof.

The present invention relates to modulators of FAS and DRs and their method of use in the treatment and prevention of diseases and pathologies related to accumulation of senescent cells during aging, such as cancer, chronic obstructive pulmonary disease (COPD), osteoarthritis, atherosclerosis, neurodegenerative diseases, diabetes, and many others. The present invention also relates to pharmaceutical compositions containing these compounds as well as various uses thereof.

The invention involves inducing 3-50 or more mutations (e.g., any whole number between 3 and 50 of mutations, with it noted that in some embodiments there can be up to 16 different RNA(s), e.g., sgRNAs each having its own a promoter, in a vector, such as AAV, and that when each sgRNA does not have its own promoter, there can be twice to thrice that amount of different RNA(s), e.g., sgRNAs, e.g., 32 or even 48 different guides delivered by one vector) in transgenic Cas9 eukaryotes to model genetic disease, e.g. cancer. The invention comprehends testing putative treatments with such models, e.g., testing putative chemical compounds that may be pharmaceutically relevant for treatment or gene therapy that may be relevant for treatment, or combinations thereof. The invention allows for the study of genetic diseases and putative treatments to better understand and alleviate a genetic disease or a condition, e.g., cancer.

The present invention is directed to the concept of sectoring antibody gene segment repertoires in order to enable the development of novel, synthetic antibody chain repertoires not seen in nature. The present invention is also directed to the realisation of the inventors that sectoring can also alter gene segment expression by providing new arrangements of gene segment clusters relative to other gene segments and regulatory elements in transgenic immunoglobulin loci, thereby providing for new synthetic antibody chain sequence repertoires. The invention also relates to gene segment inversion.

Genetically modified mice and methods and compositions for making and using the same are provided, wherein the genetic modification comprises humanization of an FcγRI protein.

The present invention relates to methods for producing a non-human animal, such as an avian, comprising a targeted germline genetic modification, the method comprising: (i) delivering a programmable nuclease to sperm; (ii) fertilizing an ovum with the sperm, and (iii) generating the animal from the ovum, wherein the nuvlease introduces the genetic modification into DNA of the prem and/or the ovum.

Non-human animal genomes, non-human animal cells, and non-human animals comprising a humanized albumin (ALB) locus and methods of making and using such non-human animal genomes, non-human animal cells, and non-human animals are provided. Non-human animal cells or non-human animals comprising a humanized albumin locus express a human albumin protein or a chimeric albumin protein, fragments of which are from human albumin. Methods are provided for using such non-human animals comprising a humanized albumin locus to assess in vivo efficacy of human-albumin-targeting reagents such as nuclease agents designed to target human albumin.

Non-human animal cells and non-human animals comprising a humanized ACE2 locus and methods of using such non-human animal cells and non-human animals are provided. Non-human animal cells or non-human animals comprising a humanized ACE2 locus express a human ACE2 protein or a chimeric ACE2 protein, fragments of which are from human ACE2. Methods are also provided for using such non-human animals comprising a humanized ACE2 locus to assess in vivo ACE2 activity, e.g., coronavirus infection and/or the treatment or prevention thereof.