The butyrophilin 1a1 knockout mouse revisited: Ablation of<i>Btn1a1</i>leads to concurrent cell death and renewal in the mammary epithelium during lactation

Jeong, Jaekwang; Kadegowda, Anil K. G.; Meyer, Thomas J.; Jenkins, Lisa M. Miller; Dinan, Jerry C.; Wysolmerski, John J.; Weigert, Roberto; Mather, Ian H.

doi:10.1096/fba.2021-00059

Cited by 7 publications

(9 citation statements)

References 89 publications

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“…Whether this cell-intrinsic JAK/STAT suppression is directly tied to the immune checkpoint activity of BTN1A1 remains unclear, but may be of clinical relevance given the essential role of JAK1-mediated signaling in IFN-mediated innate immunity 29 . Studies of BTN1A1 -/mice generated by a separate group have also suggested a role for this butyrophilin family member as a regulator of STAT3 signaling and inflammatory activity in the context of milk lipid droplet production 20 , potentially providing some degree of additional support for the present findings. Additional studies of endogenous BTN1A1 ligands and the relevance of this BTN1A1/JAK1 axis in oncogenic and immunological contexts are thus warranted.…”

Section: Discussionsupporting

confidence: 63%

“…While there is limited evidence that BTN1A1 may additionally be expressed in secondary lymphoid organs and can suppress T cell activation together with BTN2A2 19 , its regulatory role and clinical relevance in this context remain to be fully explored. BTN1A1 -/mice have also been developed, and recent systematic analyses of these animals have suggested that the loss of this butyrophilin family member is associated with enhanced inflammatory activity and activation of STAT3 signaling, further suggesting a potential regulatory role for BTN1A1 as a suppressor or immune-related and inflammatory response induction 20 . Given that BTN proteins serve as B7-related context-dependent immunosuppressive or immunostimulatory mediators, they represent promising candidate immune checkpoint proteins.…”

Section: Introductionmentioning

confidence: 99%

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BTN1A1 is a novel immune checkpoint mutually exclusive to PD-L1

Yoo

Kim

Park

et al. 2023

Preprint

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While PD-1/PD-L1 blockade is a potent antitumor treatment strategy, it is effective in only limited subsets of cancer patients, emphasizing the need for the identification of additional immune checkpoints. Butyrophilin 1A1 (BTN1A1) has been reported to exhibit potential immunoregulatory activity, but its ability to function as an immune checkpoint remains to be systematically assessed and the mechanisms underlying such activity have yet to be characterized. Here, BTN1A1 expression was validated in primary tumor tissue samples, and its ability to suppress T cell activation and T cell-dependent tumor clearance was examined. The relationship between BTN1A1 and PD-L1 expression was further characterized, and an anti-BTN1A1 antibody was developed and administered to tumor-bearing mice to test the amenability of this target to immune checkpoint inhibition. BTN1A1 was confirmed to suppress T cell activation in vitro and in vivo. Robust BTN1A1 expression was detected in a range of solid tumor tissue samples, and BTN1A1 expression was mutually exclusive with that of PD-L1 as a consequence of its inhibition of JAK/STAT signaling-induced PD-L1 upregulation. Antibody-mediated BTN1A1 blockade suppressed tumor growth and enhanced immune cell infiltration in syngeneic tumor-bearing mice. Together, these results confirm that BTN1A1 is a bona fide immune checkpoint and viable immunotherapeutic target for the treatment of anti-PD1/PD-L1 refractory or resistant patients, opening new avenues to improving survival outcomes for patients with a range of cancers.

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Section: Discussionsupporting

confidence: 63%

Section: Introductionmentioning

confidence: 99%

BTN1A1 is a novel immune checkpoint mutually exclusive to PD-L1

Yoo

Kim

Park

et al. 2023

Preprint

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“…While moving intracellularly, CLDs interact with other organelles, including the Golgi apparatus, mitochondria and casein-containing secretory vesicles (Wooding 1971, Wooding 1973, Stemberger, Walsh et al 1984, Wu, Howell et al 2000, Mather, Jack et al 2001, Honvo-Houéto, Henry et al 2016). When they arrive at the apical cytoplasm, CLDs form contacts with the apical plasma membrane via interactions between CLD-coating Plin2, cytoplasmic xanthine dehydrogenase (Xdh; also known as xanthine oxidoreductase, Xor) and the transmembrane apical plasma membrane protein butyrophilin, subfamily 1, member A1 (Btn1a1) (Ishii, Aoki et al 1995, Keenan and Patton 1995, Mather and Keenan 1998, McManaman, Palmer et al 2002, Vorbach, Scriven et al 2002, Ogg, Weldon et al 2004, Robenek, Hofnagel et al 2006, Jeong, Rao et al 2009, Monks, Dzieciatkowska et al 2016, Jeong, Kadegowda et al 2021). These proteins and their interactions allow for tight tethering, or docking, of CLDs to the apical plasma membrane, where they can continue to grow by fusion and protrude into the alveolar lumen (Dylewski, Dapper et al 1984, Masedunskas, Chen et al 2017).…”

Section: Introductionmentioning

confidence: 99%

“…Genetic disruption of the CLD synthetic machinery and docking complex components leads to poor offspring growth or starvation and death due to low milk consumption (Vorbach, Scriven et al 2002, Ogg, Weldon et al 2004, Russell, Schaack et al 2011, Wang, Lv et al 2012, Monks, Dzieciatkowska et al 2016, Zhao, Ke et al 2020, Jeong, Kadegowda et al 2021). Models targeting the CLD synthetic machinery drive low milk fat production and secretion, decreasing milk caloric content (Smith, Cases et al 2000, Beigneux, Vergnes et al 2006, Russell, Schaack et al 2011, Wang, Lv et al 2012, Suburu, Shi et al 2014), and models targeting the MFG secretion machinery drive the production of extremely large and unstable MFGs which potentially clog the ductal network, blocking overall milk secretion (Vorbach, Scriven et al 2002, Ogg, Weldon et al 2004, Monks, Dzieciatkowska et al 2016, Jeong, Kadegowda et al 2021). These mechanistic details have been worked out in dairy animals and/or model organisms by electron microscopy, immunohistochemistry & fluorescence and most recently, by elegant intravital imaging of glandular tissue (Mather, Masedunskas et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Comparative Proteomic Analysis of Paired Human Milk Fat Globules and Membranes and Mouse Milk Fat Globules Identifies Core Cellular Systems Contributing to Mammary Lipid Trafficking and Secretion

Carli

Monks

McManaman

2023

Preprint

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Human milk delivers critical nutritional and immunological support to the infant. The milk fat globule and its membrane contain many bioactive components, yet the mechanism of milk fat secretion and how milk fat globule (MFG) components are regulated are poorly defined. In this study, we perform quantitative proteomic profiling of milk fat globules from human and mouse milk, as well as from isolated membranes physically disrupted from human milk fat globules.Using paired analyses of the human samples we report membrane enrichment of the proteins involved in docking/tethering the lipid droplet to the membrane as well as minor components involved in the signaling pathway for secretion. Comparing abundance between human and mouse milk fat globules we find that 8 of 12 major milk fat globule proteins are shared between the two species. Comparative pathway enrichment analyses between human and mouse samples reveal similarities in shared membrane trafficking and signaling pathways involved in milk fat secretion. Our results advance knowledge of the composition and relative quantities of proteins in human and mouse milk fat globules in greater detail, provide a quantitative profile of specifically enriched human milk fat globule membrane proteins, and identify core cellular systems involved in milk lipid secretion.

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“…While moving intracellularly, CLDs can interact with other organelles, including the Golgi apparatus, mitochondria and casein-containing secretory vesicles ( Wooding, 1971 ; Wooding, 1973 ; Stemberger et al, 1984 ; Wu et al, 2000 ; Mather et al, 2001 ; Honvo-Houéto et al, 2016 ). When they arrive at the apical cytoplasm, CLDs form contacts with the apical plasma membrane via interactions between CLD-coating Plin2, cytoplasmic xanthine dehydrogenase (Xdh; also known as xanthine oxidoreductase, Xor) and the transmembrane plasma membrane protein butyrophilin, subfamily 1, member A1 (Btn1a1) ( Ishii et al, 1995 ; Keenan et al, 1995 ; Mather and Keenan, 1998 ; McManaman et al, 2002 ; Vorbach et al, 2002 ; Ogg et al, 2004a ; Robenek et al, 2006 ; Jeong et al, 2009 ; Monks et al, 2016 ; Jeong et al, 2021 ). These proteins and their interactions allow for tight tethering, or docking, of CLDs to the apical plasma membrane, where they can continue to grow by fusion and protrude into the alveolar lumen ( Dylewski et al, 1984 ; Monks et al, 2016 ; Masedunskas et al, 2017 ; Monks et al, 2022 ).…”

Section: Introductionmentioning

confidence: 99%

Comparative proteomic analysis of human milk fat globules and paired membranes and mouse milk fat globules identifies core cellular systems contributing to mammary lipid trafficking and secretion

Martin Carli,

Dzieciatkowska,

Hernandez

et al. 2023

Front. Mol. Biosci.

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Introduction: Human milk delivers critical nutritional and immunological support to human infants. Milk fat globules (MFGs) and their associated membranes (MFGMs) contain the majority of milk lipids and many bioactive components that contribute to neonatal development and health, yet their compositions have not been fully defined, and the mechanisms responsible for formation of these structures remain incompletely understood.Methods: In this study, we used untargeted mass spectrometry to quantitatively profile the protein compositions of freshly obtained MFGs and their paired, physically separated MFGM fractions from 13 human milk samples. We also quantitatively profiled the MFG protein compositions of 9 pooled milk samples from 18 lactating mouse dams.Results: We identified 2,453 proteins and 2,795 proteins in the majority of human MFG and MFGM samples, respectively, and 1,577 proteins in mouse MFGs. Using paired analyses of protein abundance in MFGMs compared to MFGs (MFGM-MFG; 1% FDR), we identified 699 proteins that were more highly abundant in MFGMs (MFGM-enriched), and 201 proteins that were less abundant in MFGMs (cytoplasmic). MFGM-enriched proteins comprised membrane systems (apical plasma membrane and multiple vesicular membranes) hypothesized to be responsible for lipid and protein secretion and components of membrane transport and signaling systems. Cytoplasmic proteins included ribosomal and proteasomal systems. Comparing abundance between human and mouse MFGs, we found a positive correlation (R2 = 0.44, p < 0.0001) in the relative abundances of 1,279 proteins that were found in common across species.Discussion: Comparative pathway enrichment analyses between human and mouse samples reveal similarities in membrane trafficking and signaling pathways involved in milk fat secretion and identify potentially novel immunological components of MFGs. Our results advance knowledge of the composition and relative quantities of proteins in human and mouse MFGs in greater detail, provide a quantitative profile of specifically enriched human MFGM proteins, and identify core cellular systems involved in milk lipid secretion.

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The butyrophilin 1a1 knockout mouse revisited: Ablation ofBtn1a1leads to concurrent cell death and renewal in the mammary epithelium during lactation

Cited by 7 publications

References 89 publications

BTN1A1 is a novel immune checkpoint mutually exclusive to PD-L1

BTN1A1 is a novel immune checkpoint mutually exclusive to PD-L1

Comparative Proteomic Analysis of Paired Human Milk Fat Globules and Membranes and Mouse Milk Fat Globules Identifies Core Cellular Systems Contributing to Mammary Lipid Trafficking and Secretion

Comparative proteomic analysis of human milk fat globules and paired membranes and mouse milk fat globules identifies core cellular systems contributing to mammary lipid trafficking and secretion

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