Novel compounds comprising a guanidine-rich head covalently coupled to one or more oligonucleotide antisense sequences which are useful to modulate blood coagulation by affecting the expression of integrin αIIb or β3 are described herein. This invention also includes pharmaceutical compositions containing these compounds, with or without other therapeutic agents, and to methods of using these compounds as inhibitor of platelet aggregation, as thrombolytics, and/or for the treatment of other thromboembolic disorders. Vivo-MOs, which include eight guanidine groups dendrimerically arranged in the guanidine-rich head and two synthetic antisense morpholino oligonucleotides, are representative compounds of the present invention.

A method to evaluate the potential of cancer therapeutics to produce skin related side effects is disclosed. The method, which involves use of biological markers, can also be used to evaluate the efficacy of a composition in reducing the effects of cancer therapeutics on skin.

The present disclosure relates to compounds that bind to at least one of ACAT1/2 and OXCT1/2 and inhibit mitochondrial ATP production, referred to herein as mitoketoscins. Methods of screening compounds for mitochondrial inhibition and anti-cancer properties are disclosed. Also described are methods of using mitoketoscins to prevent or treat cancer, bacterial infections, and pathogenic yeast, as well as methods of using mitoketoscins to provide anti-aging benefits. Specific mitoketoscin compounds are also disclosed.

The present disclosure relates to compounds that bind to at least one of ACAT1/2 and OXCT1/2 and inhibit mitochondrial ATP production, referred to herein as mitoketoscins. Methods of screening compounds for mitochondrial inhibition and anti-cancer properties are disclosed. Also described are methods of using mitoketoscins to prevent or treat cancer, bacterial infections, and pathogenic yeast, as well as methods of using mitoketoscins to provide anti-aging benefits. Specific mitoketoscin compounds are also disclosed.

Provided are methods for identifying differentially represented genes, the method comprising the steps of generating a pool of mutant bacteria by transposon mutagenesis with an activating transposon (Tn.sub.A), wherein the Tn.sub.A comprises a promoter such that transposon insertion into bacterial DNA increases the transcription of a gene at or near the insertion site; growing bacteria from the mutant pool in the presence of different amounts of said antibiotic to produce two or more test cultures; and comparing the distribution of Tn.sub.A insertions between test cultures.

Provided are methods for identifying differentially represented genes, the method comprising the steps of generating a pool of mutant bacteria by transposon mutagenesis with an activating transposon (Tn.sub.A), wherein the Tn.sub.A comprises a promoter such that transposon insertion into bacterial DNA increases the transcription of a gene at or near the insertion site; growing bacteria from the mutant pool in the presence of different amounts of said antibiotic to produce two or more test cultures; and comparing the distribution of Tn.sub.A insertions between test cultures.

Methods for Identifying protein modulators of eukaryotic cells by expressing a combinatorial library of potential agonists inside a eukaryotic cell and then directly selecting for an agonist of a target molecule. Some methods involve co-culturing a cell expressing a combinatorial library of potential agonists and a second cell, and then selecting agents that modulate a phenotype of or a desired cellular response in the second cell. Preferably, the agonists are antibodies introduced into and expressed in the starting cells, such as agonist anti-EpoR, anti-TpoR, or G-CSFR antibodies. Also disclosed are methods for selecting from combinatorial antibody libraries bispecific antibodies that can regulate cell phenotypes.

Methods for Identifying protein modulators of eukaryotic cells by expressing a combinatorial library of potential agonists inside a eukaryotic cell and then directly selecting for an agonist of a target molecule. Some methods involve co-culturing a cell expressing a combinatorial library of potential agonists and a second cell, and then selecting agents that modulate a phenotype of or a desired cellular response in the second cell. Preferably, the agonists are antibodies introduced into and expressed in the starting cells, such as agonist anti-EpoR, anti-TpoR, or G-CSFR antibodies. Also disclosed are methods for selecting from combinatorial antibody libraries bispecific antibodies that can regulate cell phenotypes.

The present invention relates to the fields of molecular medicine and targeted delivery of therapeutic or diagnostic agents to cells outside the vascular system and into the parenchymal tissue of organs within the body. More specifically, the present invention relates to the methods used to identify membrane receptors or transporters capable of carrying cargo specifically targeted to the parenchymal tissue of the brain and to in vivo enrichment methods for selecting peptides that are transported across the blood-brain barrier (“BBB”), or analogously, across other membrane containing organs or structures, such as liver, spleen, kidney and tumors.

The present disclosure provides ultrahigh-throughput single cell genomic sequencing methods, referred to herein as “SiC-seq”, which methods include encapsulating single cells in molten gel droplets to facilitate bulk cell lysis and purification of genomic DNA in microgels. Systems and devices for practicing the subject methods are also provided.