Identification of lamprey variable lymphocyte receptors that target the brain vasculature

Lajoie, Jason; Katt, Moriah E.; Waters, Elizabeth A; Herrin, Brantley R.; Shusta, Eric V.

doi:10.1038/s41598-022-09962-8

Cited by 8 publications

(7 citation statements)

References 80 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Recent work demonstrated the utility of YDIP screening using an in vivo‐sourced cell lysate antigen pool which holds the promise of increased in vivo relevance of the output binding pool. [ 25 ] A YSD library of variable lymphocyte receptors (VLRs) was generated from lamprey that were immunized with brain endothelial cell plasma membranes directly fractioned from mouse brain microvessels. [ 25 ] To enrich the library for brain endothelial cell membrane targeted VLRs, YDIP was performed using an antigen pool comprising detergent‐solubilized, biotinylated lysates of the same mouse brain microvessel plasma membranes that were used for lamprey immunization.…”

Section: Screening Against Nontraditional Cellular Antigensmentioning

confidence: 99%

“…[ 25 ] A YSD library of variable lymphocyte receptors (VLRs) was generated from lamprey that were immunized with brain endothelial cell plasma membranes directly fractioned from mouse brain microvessels. [ 25 ] To enrich the library for brain endothelial cell membrane targeted VLRs, YDIP was performed using an antigen pool comprising detergent‐solubilized, biotinylated lysates of the same mouse brain microvessel plasma membranes that were used for lamprey immunization. [ 25 ] YDIP with one round of magnetic activated cell sorting (MACS) followed by one round of FACS led to a tenfold enrichment in yeast‐displayed VLRs capable of binding brain microvessel plasma membrane compared to the starting library.…”

Section: Screening Against Nontraditional Cellular Antigensmentioning

confidence: 99%

“…[ 25 ] To enrich the library for brain endothelial cell membrane targeted VLRs, YDIP was performed using an antigen pool comprising detergent‐solubilized, biotinylated lysates of the same mouse brain microvessel plasma membranes that were used for lamprey immunization. [ 25 ] YDIP with one round of magnetic activated cell sorting (MACS) followed by one round of FACS led to a tenfold enrichment in yeast‐displayed VLRs capable of binding brain microvessel plasma membrane compared to the starting library. [ 25 ] Subsequent selection of the library for VLRs that could bind extracellular epitopes was performed by biopanning against mouse brain endothelial cell cultures.…”

Section: Screening Against Nontraditional Cellular Antigensmentioning

confidence: 99%

“…[ 25 ] YDIP with one round of magnetic activated cell sorting (MACS) followed by one round of FACS led to a tenfold enrichment in yeast‐displayed VLRs capable of binding brain microvessel plasma membrane compared to the starting library. [ 25 ] Subsequent selection of the library for VLRs that could bind extracellular epitopes was performed by biopanning against mouse brain endothelial cell cultures. [ 25 ] While biopanning for enrichment of VLRs binding to extracellular targets was performed using cell cultured substrates rather than in vivo sourced cell lysates, the initial enrichment of the library using the brain endothelial plasma membranes ensured that the resulting pool of VLRs had many variants (16 of 26 clones tested) that could bind relevant antigens in brain microvessels.…”

Section: Screening Against Nontraditional Cellular Antigensmentioning

confidence: 99%

See 3 more Smart Citations

Protein Engineering and High‐Throughput Screening by Yeast Surface Display: Survey of Current Methods

Lopez-Morales,

Vanella,

Appelt

et al. 2023

Small Science

Self Cite

View full text Add to dashboard Cite

Yeast surface display (YSD) is a powerful tool in biotechnology that links genotype to phenotype. In this review, the latest advancements in protein engineering and high‐throughput screening based on YSD are covered. The focus is on innovative methods for overcoming challenges in YSD in the context of biotherapeutic drug discovery and diagnostics. Topics ranging from titrating avidity in YSD using transcriptional control to the development of serological diagnostic assays relying on serum biopanning and mitigation of unspecific binding are covered. Screening techniques against nontraditional cellular antigens, such as cell lysates, membrane proteins, and extracellular matrices are summarized and techniques are further delved into for expansion of the chemical repertoire, considering protein–small molecule hybrids and noncanonical amino acid incorporation. Additionally, in vivo gene diversification and continuous evolution in yeast is discussed. Collectively, these techniques enhance the diversity and functionality of engineered proteins isolated via YSD, broadening the scope of applications that can be addressed. The review concludes with future perspectives and potential impact of these advancements on protein engineering. The goal is to provide a focused summary of recent progress in the field.

show abstract

Section: Screening Against Nontraditional Cellular Antigensmentioning

confidence: 99%

Section: Screening Against Nontraditional Cellular Antigensmentioning

confidence: 99%

Section: Screening Against Nontraditional Cellular Antigensmentioning

confidence: 99%

Section: Screening Against Nontraditional Cellular Antigensmentioning

confidence: 99%

See 2 more Smart Citations

Protein Engineering and High‐Throughput Screening by Yeast Surface Display: Survey of Current Methods

Lopez-Morales,

Vanella,

Appelt

et al. 2023

Small Science

Self Cite

View full text Add to dashboard Cite

show abstract

“…At the time we submitted our article, a lamprey immunization with murine brain microvessels plasma membranes with the aim of discovering new brain targeting receptors was published by J.M. Lajoie et al [ 32 ]. The first goal of the present report is to describe such an approach of generating an immune library from immunized mice and screening the resulting antibodies based on binding, internalization and finally transcytosis.…”

Section: Introductionmentioning

confidence: 99%

An innovative strategy to identify new targets for delivering antibodies to the brain has led to the exploration of the integrin family

et al. 2022

View full text Add to dashboard Cite

Background Increasing brain exposure of biotherapeutics is key to success in central nervous system disease drug discovery. Accessing the brain parenchyma is especially difficult for large polar molecules such as biotherapeutics and antibodies because of the blood-brain barrier. We investigated a new immunization strategy to identify novel receptors mediating transcytosis across the blood-brain barrier. Method We immunized mice with primary non-human primate brain microvascular endothelial cells to obtain antibodies. These antibodies were screened for their capacity to bind and to be internalized by primary non-human primate brain microvascular endothelial cells and Human Cerebral Microvascular Endothelial Cell clone D3. They were further evaluated for their transcytosis capabilities in three in vitro blood-brain barrier models. In parallel, their targets were identified by two different methods and their pattern of binding to human tissue was investigated using immunohistochemistry. Results 12 antibodies with unique sequence and internalization capacities were selected amongst more than six hundred. Aside from one antibody targeting Activated Leukocyte Cell Adhesion Molecule and one targeting Striatin3, most of the other antibodies recognized β1 integrin and its heterodimers. The antibody with the best transcytosis capabilities in all blood-brain barrier in vitro models and with the best binding capacity was an anti-αnβ1 integrin. In comparison, commercial anti-integrin antibodies performed poorly in transcytosis assays, emphasizing the originality of the antibodies derived here. Immunohistochemistry studies showed specific vascular staining on human and non-human primate tissues. Conclusions This transcytotic behavior has not previously been reported for anti-integrin antibodies. Further studies should be undertaken to validate this new mechanism in vivo and to evaluate its potential in brain delivery.

show abstract

The Variable Lymphocyte Receptor B System of the Jawless Vertebrates

Boehm,

Cooper,

Hirano

et al. 2024

Molecular Biology of B Cells

View full text Add to dashboard Cite

Identification of lamprey variable lymphocyte receptors that target the brain vasculature

Cited by 8 publications

References 80 publications

Protein Engineering and High‐Throughput Screening by Yeast Surface Display: Survey of Current Methods

Protein Engineering and High‐Throughput Screening by Yeast Surface Display: Survey of Current Methods

An innovative strategy to identify new targets for delivering antibodies to the brain has led to the exploration of the integrin family

The Variable Lymphocyte Receptor B System of the Jawless Vertebrates

Contact Info

Product

Resources

About