Photoactive Protein Research Articles

Mimicking Microbial Rhodopsin Isomerization in a Single Crystal.

Bacteriorhodopsin represents the simplest, and possibly most abundant, phototropic system requiring only a retinal-bound transmembrane protein to convert photons of light to an energy-generating proton gradient. The creation and interrogation of a microbial rhodopsin mimic, based on an orthogonal protein system, would illuminate the design elements required to generate new photoactive proteins with novel function. We describe a microbial rhodopsin mimic, created using a small soluble protein as a template, that specifically photoisomerizes all- trans to 13- cis retinal followed by thermal relaxation to the all- trans isomer, mimicking the bacteriorhodopsin photocycle, in a single crystal. The key element for selective isomerization is a tuned steric interaction between the chromophore and protein, similar to that seen in the microbial rhodopsins. It is further demonstrated that a single mutation converts the system to a protein photoswitch without chromophore photoisomerization or conformational change.

Photoactivation Mechanism, Timing of Protein Secondary Structure Dynamics and Carotenoid Translocation in the Orange Carotenoid Protein.

The orange carotenoid protein (OCP) is a two-domain photoactive protein that noncovalently binds an echinenone (ECN) carotenoid and mediates photoprotection in cyanobacteria. In the dark, OCP assumes an orange, inactive state known as OCPO; blue light illumination results in the red active state, known as OCPR. The OCPR state is characterized by large-scale structural changes that involve dissociation and separation of C-terminal and N-terminal domains accompanied by carotenoid translocation into the N-terminal domain. The mechanistic and dynamic-structural relations between photon absorption and formation of the OCPR state have remained largely unknown. Here, we employ a combination of time-resolved UV–visible and (polarized) mid-infrared spectroscopy to assess the electronic and structural dynamics of the carotenoid and the protein secondary structure, from femtoseconds to 0.5 ms. We identify a hereto unidentified carotenoid excited state in OCP, the so-called S* state, which we propose to play a key role in breaking conserved hydrogen-bond interactions between carotenoid and aromatic amino acids in the binding pocket. We arrive at a comprehensive reaction model where the hydrogen-bond rupture with conserved aromatic side chains at the carotenoid β1-ring in picoseconds occurs at a low yield of <1%, whereby the β1-ring retains a trans configuration with respect to the conjugated π-electron chain. This event initiates structural changes at the N-terminal domain in 1 μs, which allow the carotenoid to translocate into the N-terminal domain in 10 μs. We identified infrared signatures of helical elements that dock on the C-terminal domain β-sheet in the dark and unfold in the light to allow domain separation. These helical elements do not move within the experimental range of 0.5 ms, indicating that domain separation occurs on longer time scales, lagging carotenoid translocation by at least 2 decades of time.

Antarctic heterotrophic bacterium Hymenobacter nivis P3T displays light-enhanced growth and expresses putative photoactive proteins.

Hymenobacter nivis P3T is a heterotrophic bacterium isolated from Antarctic red snow generated by algal blooms. Despite being non-photosynthetic, H. nivis was dominantly found in the red snow environment that is exposed to high light and UV irradiation, suggesting that this species can flourish under such harsh conditions. In order to further understand the adaptive strategies on the snow surface environment of Antarctica, the genome of H. nivis P3T was sequenced and analyzed, which identified genes putatively encoding for light-reactive proteins such as proteorhodopsin, phytochrome, photolyase and several copies of cryptochromes. Culture-based experiments revealed that H. nivis P3T growth was significantly enhanced under light conditions, while dark conditions had increased extracellular polymeric substances. Furthermore, the expression of several putative light-reactive proteins was determined by proteomic analysis. These results indicate that H. nivis P3T is able to potentially utilize light, which may explain its dominance on the red snow surface environment of Antarctica. ORIGINALITY-SIGNIFICANCE STATEMENT: The role of proteorhodopsin in heterotrophic bacteria is not well-characterized, as only a handful of proteorhodopsin-harbouring isolates were shown to have a light-enhanced phenotype through culture-based experiments to date. This is the first study that demonstrates light-stimulated growth and protein expression evidence of photoactive proteins for a non-marine psychrophile and for a member of the genus Hymenobacter. It is also the first study that provides comprehensive proteome information for this genus. This study presents significant results in understanding the adaptive mechanism of a heterotrophic non-photosynthetic bacterium thriving on the snow surface environment of Antarctica as well as demonstrating the role of light-utilization in promoting growth, possibly through proteorhodopsin.

Tunable photocycle kinetics of a hybrid bacteriorhodopsin/quantum dot system

The inclusion of inorganic nanoparticles in biological environments has led to the creation of hybrid nanosystems that are employed in a variety of applications. One such system includes quantum dots (QDs) coupled with the photoactive protein, bacteriorhodopsin (BR), which has been explored in developing enhanced photovoltaic devices. In this work, we have discovered that the kinetics of the BR photocycle can be manipulated using CdSe/CdS (core/shell) QDs. The photocycle lifetime of protein samples with varying QD amounts were monitored using time-resolved absorption spectroscopy. Concentration-dependent elongations of the bR and M state lifetimes were observed in the kinetic traces, thus suggesting that excitonic coupling occurs between BR and QDs. We propose that the pairing of BR with QDs has the potential to be utilized in protein-based computing applications, specifically for real-time holographic processors, which depend on the temporal dynamics of the bR and M photointermediates.

Inmovilización de la proteína fotoactiva bacteriorodopsina sobre óxido de zinc Aplicación en Celdas Solares Bio-Sensibilizadas

En este proyecto se construyeron fotoánodos para celdas solares sensibilizadas utilizando la proteína fotoactiva bacteriorodopsina (BR). El objetivo fue utilizar la proteína como sustituyente a los colorantes comunes a base de Ru, que son costosos y tóxicos. Los sustratos se prepararon recubriendo vidrio conductor con nanopartículas de óxido de zinc (ZnO-NPs). La proteína se inmovilizó en estos sustratos para completar un fotoánodo capaz de capturar la energía solar y transformarla en energía eléctrica. Las técnicas de dropcasting (DC), funcionalización química con feniltrietoxisilano (PTES) y la sedimentación electroforética (SE) fueron optimizadas para inmovilizar la proteína. Mediante espectroscopia de absorción ultravioleta-visible (UV-Vis) se demostró que la proteína conservaba su función fotoactiva después de la inmovilización. La resistencia y tasa de transferencia de carga del fotoánodo en el electrolito fue comparada por medio de impedancia electroquímica. Para los tres métodos se encontraron valores relativamente altos (105 Ω) en comparación con datos reportados para tintes de rutenio. El desempeño de los fotoánodos preparados por DC y SE en celdas solares sensibilizadas se determinó por cronopotenciometría bajo iluminación. Se encontró que la capa molecular de PTES permite inmovilizar la proteína en periodos más cortos de tiempo pero introduce una resistencia eléctrica adicional en el sistema, por lo que no es apropiada para el sistema fotoelectroquímico estudiado. Los fotoánodos preparados por SE permite obtener el fotovoltaje más alto (16 mV) y la tasa de transferencia electrónica más veloz, mientras que usando la técnica DC se midieron fotovoltajes de tan solo 1 mV. Estas respuestas sugieren que la orientación de la proteína en el ZnO es determinante en la fotorespuesta de la celda, ya que bajo el campo eléctrico aplicado durante SE la proteína se orienta según su dipolo eléctrico, mientras en el DC, la orientación es aleatoria. En base a los resultados obtenidos, se recomienda controlar mejor el espesor de la capa de la proteína, utilizar un electrolito más afín a la naturaleza de esta biomolécula y disminuir la rugosidad de la capa de ZnO para producir fotoánodos que transformen la energía solar de forma más eficiente.

Identification of PAmKate as a Red Photoactivatable Fluorescent Protein for Cryogenic Super-Resolution Imaging.

Single-molecule super-resolution fluorescence microscopy conducted in vitrified samples at cryogenic temperatures offers enhanced localization precision due to reduced photobleaching rates, a chemical-free and rapid fixation method, and the potential of correlation with cryogenic electron microscopy. Achieving cryogenic super-resolution microscopy requires the ability to control the sparsity of emissive labels at cryogenic temperatures. Obtaining this control presents a key challenge for the development of this technique. In this work, we identify a red photoactivatable protein, PAmKate, which remains activatable at cryogenic temperatures. We characterize its activation as a function of temperature and find that activation is efficient at cryogenic and room temperatures. We perform cryogenic super-resolution experiments in situ, labeling PopZ, a protein known to assemble into a microdomain at the poles of the model bacterium Caulobacter crescentus. We find improved localization precision at cryogenic temperatures compared to room temperature by a factor of 4, attributable to reduced photobleaching.

Photocage-initiated time-resolved solution X-ray scattering investigation of protein dimerization.

This work demonstrates a new method for investigating time-resolved structural changes in protein conformation and oligomerization via photocage-initiated time-resolved X-ray solution scattering by observing the ATP-driven dimerization of the MsbA nucleotide-binding domain. Photocaged small molecules allow the observation of single-turnover reactions of non-naturally photoactivatable proteins. The kinetics of the reaction can be derived from changes in X-ray scattering associated with ATP-binding and subsequent dimerization. This method can be expanded to any small-molecule-driven protein reaction with conformational changes traceable by X-ray scattering where the small molecule can be photocaged.

Discovering Selective Binders for Photoswitchable Proteins Using Phage Display.

Nature provides an array of proteins that change conformation in response to light. The discovery of a complementary array of proteins that bind only the light-state or dark-state conformation of their photoactive partner proteins would allow each light-switchable protein to be used as an optogenetic tool to control protein-protein interactions. However, as many photoactive proteins have no known binding partner, the advantages of optogenetic control-precise spatial and temporal resolution-are currently restricted to a few well-defined natural systems. In addition, the affinities and kinetics of native interactions are often suboptimal and are difficult to engineer in the absence of any structural information. We report a phage display strategy using a small scaffold protein that can be used to discover new binding partners for both light and dark states of a given light-switchable protein. We used our approach to generate binding partners that interact specifically with the light state or the dark state conformation of two light-switchable proteins: PYP, a test case for a protein with no known partners, and AsLOV2, a well-characterized protein. We show that these novel light-switchable protein-protein interactions can function in living cells to control subcellular localization processes.

Reversible Control of Protein Localization in Living Cells Using a Photocaged-Photocleavable Chemical Dimerizer.

Many dynamic biological processes are regulated by protein-protein interactions and protein localization. Experimental techniques to probe such processes with temporal and spatial precision include photoactivatable proteins and chemically induced dimerization (CID) of proteins. CID has been used to study several cellular events, especially cell signaling networks, which are often reversible. However, chemical dimerizers that can be both rapidly activated and deactivated with high spatiotemporal resolution are currently limited. Herein, we present a novel chemical inducer of protein dimerization that can be rapidly turned on and off using single pulses of light at two orthogonal wavelengths. We demonstrate the utility of this molecule by controlling peroxisome transport and mitotic checkpoint signaling in living cells. Our system highlights and enhances the spatiotemporal control offered by CID. This tool addresses biological questions on subcellular levels by controlling protein-protein interactions.

Photocurrent generation of biohybrid systems based on bacterial reaction centers and graphene electrodes

The direct conversion of sunlight into chemical energy via photosynthesis is a unique capability of plants and some bacterial species. Aimed at mimicking this energy conversion process, the combination of inorganic substrates and organic photoactive proteins into an artificial biohybrid system is of a great interest for artificial bio-photovoltaic applications. It also allows to better understand charge transfer processes involved in the photosynthetic chain. In this work, single layer graphene (SLG) and multilayer graphene (MLG) electrodes are used as a platform for the immobilization of reaction centers (RCs) from purple bacteria Rhodobacter sphaeroides, a protein complex responsible for the generation of photo-excited charges. Electrochemical experiments with graphene electrodes and redox molecules reveal fundamental differences in the charge transfer processes for SLG and MLG films. We demonstrate that both graphene-based materials enable the immobilization of RCs without loss of functionality, attested by a photocurrent generation under illumination with IR-light at a wavelength of 870 nm. Furthermore, we report on the dependence of the generated photocurrent on the applied bias voltage, as well as on the presence of charge mediators in the surrounding electrolyte. This work demonstrates that SLG and MLG are a suitable platform for RC immobilization and subsequent photocurrent generation, suggesting a promising potential for graphene-based materials in bio-photovoltaics.

Protomer-Dependent Electronic Spectroscopy and Photochemistry of the Model Flavin Chromophore Alloxazine.

Flavin chromophores play key roles in a wide range of photoactive proteins, but key questions exist in relation to their fundamental spectroscopic and photochemical properties. In this work, we report the first gas-phase spectroscopy study of protonated alloxazine (AL∙H+), a model flavin chromophore. Laser photodissociation is employed across a wide range (2.34–5.64 eV) to obtain the electronic spectrum and characterize the photofragmentation pathways. By comparison to TDDFT quantum chemical calculations, the spectrum is assigned to two AL∙H+ protomers; an N5 (dominant) and O4 (minor) form. The protomers have distinctly different spectral profiles in the region above 4.8 eV due to the presence of a strong electronic transition for the O4 protomer corresponding to an electron-density shift from the benzene to uracil moiety. AL∙H+ photoexcitation leads to fragmentation via loss of HCN and HNCO (along with small molecules such as CO2 and H2O), but the photofragmentation patterns differ dramatically from those observed upon collision excitation of the ground electronic state. This reveals that fragmentation is occurring during the excited state lifetime. Finally, our results show that the N5 protomer is associated primarily with HNCO loss while the O4 protomer is associated with HCN loss, indicating that the ring-opening dynamics are dependent on the location of protonation in the ground-state molecule.

Mutation Study of Heliorhodopsin 48C12.

Rhodopsins are heptahelical transmembrane photoactive protein families: type 1 (microbial rhodopsins) and type 2 (animal rhodopsins). Both families share similar topologies and chromophore retinal, which is linked covalently as a protonated Schiff base to a Lys at the transmembrane 7 helix. Recently, through functional metagenomics analysis, we reported an unnoticed diverse family, heliorhodopsins (HeRs), which are abundant and distributed globally in archaea, bacteria, eukarya, and viruses. The sequence identity is <15% between HeRs and type 1 rhodopsins, so that many aspects of the molecular properties of HeRs remain unknown. Herein, to gain information about the residues responsible for the interaction with the chromophore, we applied Ala scanning to 30 candidate residues in HeR 48C12. As a result, 12 mutants showed no absorption change, eight exhibited a spectral blue-shift, six exhibited a spectral red-shift, and four did not form a pigment. R104, Y108, G145, and K241 play crucial roles in pigment formation. A combination of single mutants successfully engineered pigments absorbing at 523 nm (S112A/M141A) and 571 nm (H80A/S237A), covering more than ∼50 nm. These results provide fundamental knowledge about the molecular properties of HeRs.

Nanocatalyst Complex Can Dephosphorylate Key Proteins in MAPK Pathway for Cancer Therapy

Controlling phosphorylation processes of proteins is a facile way for manipulating cell fates. Herein, a synergistic therapeutic strategy utilizing a near-infrared (NIR)-responsive nanocatalyst (NC) complex is presented, which is comprised of photoactive NC and protein phosphatase 2A (PP2A), to synergistically inhibit hyperphosphorylation of mitogen-activated protein kinase (MAPK) pathway for cancer therapy, as an example of many biological processes this approach can apply to. NIR-triggered release of PP2A specially dephosphorylates and inactivates mitogen-activated protein kinase kinase (MAP2K, also known as MEK) and extracellular regulated protein kinases (ERK) in the MAPK pathway, meanwhile, the NIR-triggered activation of NC decreases the level of intracellular adenosine triphosphate to attenuate protein phosphorylation of MEK and ERK. The synergistic therapeutics effectively suppress melanoma progression by inhibiting hyperphosphorylation of the MAPK pathway. In addition, the nanocatalyst complex reduces the risk of drug-resistance through inhibiting a rebound of RAS-GTP. The NIR-responsive nanocatalyst complex paves a novel way for cancer therapeutics.

Purification and biochemical characterization of photo-active membrane protein bacteriorhodopsin from Haloarcula marismortui, an extreme halophile from the Dead Sea

Bacteriorhodopsin (BR) is an exciting photo-active retinal protein with many potential industrial applications. In this study, BR from the extremely halophilic archaeon Haloarcula marismortui (HmBR) was purified successfully using aqueous two phase extraction method. Absorption spectroscopy analysis showed maximum absorption peak of HmBR retinal protein (λmax) at 415 nm. The purified HmBR was visualized by SDS-PAGE, with a subunit molecular mass of 27 kDa, and its identity was confirmed by resonance Raman spectroscopy, Fourier transform infrared spectroscopy and atomic force microscopy. The effect of pH and salt concentration on the absorption spectrum of HmBR was evaluated. Red-shifted in λmax of HmBR was recorded at acidic condition (pH 5) and HmBR showed remarkable optical activity under high salinity condition. The photoelectric activity of HmBR was evaluated by measuring the DC-voltage generated from HmBR coated on indium tin oxide (ITO) glass when light illumination was applied.

Temporal control of growth factor‐mediated signaling pathways during cell differentiation and Xenopus embryonic development

Growth factor‐mediated signaling pathways regulate a wide‐spectrum of cellular functions such as survival, proliferation, differentiation, and apoptosis. Different growth factors typically trigger the activation of the same set of downstream signaling pathways which includes the mitogen activated protein kinase (MAPK), phosphoinositide 3‐kinase (PI3K)‐AKT, and phospholipase C (PLC) pathways Evidence suggests that precise spatiotemporal regulation of these signaling pathways is involved in generating diverse cellular outcomes. Although conventional genetic and pharmacological approaches have helped us understand different aspects of signaling pathways, a quantitative delineation of their signaling kinetics is pending due to a lack of tools that allow for precise temporal control of these pathways. Non‐neuronal optogenetics, an emerging technique that utilizes light to control intracellular signaling pathways, is a remarkable tool to help achieve this goal. Here, we introduce a bicistronic optogenetic system which we recently developed in our laboratory to achieve temporal control of the MAPK pathway. This tool uses the photoactivatable protein cryptochrome 2 (CRY2) and the N‐terminal domain of cryptochrome‐interacting basic‐helix‐loop‐helix (CIBN) from Arabidopsis thaliana. This novel system allows reversible, light‐mediated activation of the MAPK signaling pathway in intact mammalian cells as well as in developing Xenopus laevis embryos. In PC12 neuronal cells, light‐controlled, intermittent MAPK activity reveals a memory effect in light‐induced neurite outgrowth. In Xenopus embryos, developmental stage‐specific MAPK activation further reveals that this pathway can reprogram cell fate after a crucial time window when germ layers are specified. Our strategy can be generalized to control other kinase pathways with a similar activation mechanism. Results from our research will help resolve intracellular mechanisms of growth factor‐mediated signal transduction during cell differentiation and embryonic development.Support or Funding InformationKai Zhang, Department of Biochemistry, University of Illinois Urbana‐ChampaignThis abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Functional interaction of low-homology FRPs from different cyanobacteria with Synechocystis OCP

Photosynthesis requires a balance between efficient light harvesting and protection against photodamage. The cyanobacterial photoprotection system uniquely relies on the functioning of the photoactive orange carotenoid protein (OCP) that under intense illumination provides fluorescence quenching of the light-harvesting antenna complexes, phycobilisomes. The recently identified fluorescence recovery protein (FRP) binds to the photoactivated OCP and accelerates its relaxation into the basal form, completing the regulatory circle. The molecular mechanism of FRP functioning is largely controversial. Moreover, since the available knowledge has mainly been gained from studying Synechocystis proteins, the cross-species conservation of the FRP mechanism remains unexplored. Besides phylogenetic analysis, we performed a detailed structural-functional analysis of two selected low-homology FRPs by comparing them with Synechocystis FRP (SynFRP). While adopting similar dimeric conformations in solution and preserving binding preferences of SynFRP towards various OCP variants, the low-homology FRPs demonstrated distinct binding stoichiometries and differentially accentuated features of this functional interaction. By providing clues to understand the FRP mechanism universally, our results also establish foundations for upcoming structural investigations necessary to elucidate the FRP-dependent regulatory mechanism.

Photoactive Split Green Fluorescent Protein: Engineering a New Optogenetic and Imaging System

Visible light is a non-invasive reagent with the potential to control molecular processes with high spatiotemporal resolution, offering a unique approach to biotechnology. Many light-sensitive small molecules and proteins have been used to photochemically control, or “cage”, biologically active molecules. Initially suppressed, the molecule's activity is recovered with light. As versatile in vivo tools, these photocaged molecules have applications in drug delivery, gene regulation, biosensing, and imaging. However, current photocaging systems are limited by large size, restrictive cellular localization, toxic excitation wavelengths, and the need for exogenous chromophores. While green fluorescent proteins (GFPs) are well-established imaging tools, recent findings indicate split GFPs have the potential to function as genetically-encoded photocaging reagents without the limitations of other systems [1]. To optimize the light sensitivity of split GFP photocaging with directed evolution, we designed and tested a functional assay that directly links split GFP's photoresponse to transcription of a reporter gene. We then developed a complex, two-part high-throughput screen based on reporter gene expression to select for improved light sensitivity among split GFP variants. A new multipurpose protein engineering platform called μSCALE (microcapillary single-cell analysis and laser extraction) allowed for the rapid visualization of mutant libraries and subsequent isolation of variants with the desired phenotype [2]. In addition to the practical applications of an improved photocage, characterization and mutational analysis of the evolved, light-activated split GFP variants provide insight into the coupling between the chromophore excited state and protein dynamics, which broadly impacts our understanding of diverse photobiological systems. 1. Lin, C.-Y. et al. Proc. Nat. Acad. Sci. 2017, 114 (11), 2146-2155. 2. Chen, B. et al. Nat. Chem. Biol. 2016, 12 (2), 76–81.

Microbial Rhodopsins.

Microbial rhodopsins (MRs) are a large family of photoactive membrane proteins, found in microorganisms belonging to all kingdoms of life, with new members being constantly discovered. Among the MRs are light-driven proton, cation and anion pumps, light-gated cation and anion channels, and various photoreceptors. Due to their abundance and amenability to studies, MRs served as model systems for a great variety of biophysical techniques, and recently found a great application as optogenetic tools. While the basic aspects of microbial rhodopsins functioning have been known for some time, there is still a plenty of unanswered questions. This chapter presents and summarizes the available knowledge, focusing on the functional and structural studies.

Internal rulers to assess fluorescent protein photoactivation efficiency.

Photoactivatable fluorescent proteins (PA-FPs) have been widely used to assess the dynamics of cell biological processes. In addition, PA-FPs enabled single-molecule based super-resolution imaging (photoactivated localization microscopy) and thereby provided unprecedented structural insight. For the lack of tools, however, the fraction of PA-FPs that is, actually being switched on to fluoresce, that is, the photoactivation efficiency, has been difficult to assess. Uncertainty about photoactivation efficiency has hampered an understanding of the absolute amount of PA-FPs, that is, being examined. Here, we present internal rulers to assess photoactivation efficiencies of photoactivatable proteins. These internal rulers comprise a PA-FP that is genetically directly coupled to a spectrally distinct always-on fluorescent protein. Thus, these fluorescent proteins will be expressed in the bacterial and mammalian cell in a one-to-one ratio. With these tools, we describe photoactivation efficiencies of PA-GFP and PA-Cherry in intensity-based ratiometric ensemble studies and on the single-molecule level. In ratiometric ensemble studies, we show that photoactivation efficiency depends on how the PA-FPs are exposed to 405nm light. Using a laser-scanning microscope, hundreds of iterative low-level exposures are up to four times more efficient than a short high-power exposure. Using wide-field illumination, photoactivation was similarly efficient and instantaneous. These findings suggest that the repetitive or stochastic exposure to photons of 405nm light results in more efficient photoactivation than a continuous flow of photons. Because of the differential photoactivation efficiency, it is crucial to assess photoactivation efficiency for any given experimental set-up. The tools we provide can be applied to any genetically encoded photoactivatable protein. Determination of photoactivation efficiency is essential for an understanding of absolute molecule numbers in ensemble studies and, most importantly, quantitative superresolution imaging. © 2017 International Society for Advancement of Cytometry.

Specific capture, recovery and culture of cancer cells using oriented antibody-modified polystyrene chips coated with agarose film

Agarose gel can be used for three dimensional (3D) cell culture because it prevents cell attachment. The dried agarose film coated on a culture plate also protected cell attachment and allowed 3D growth of cancer cells. We developed an efficient method for agarose film coating on an oxygen-plasma treated micropost polystyrene chip prepared by an injection molding process. The agarose film was modified to maleimide or Ni-NTA groups for covalent or cleavable attachment of photoactivatable Fc-specific antibody binding proteins (PFcBPs) via their N-terminal cysteine residues or 6xHis tag, respectively. The antibodies photocrosslinked onto the PFcBP-modified chips specifically captured the target cells without nonspecific binding, and the captured cells grew 3D modes on the chips. The captured cells on the cleavable antibody-modified chips were easily recovered by treatment of commercial trypsin-EDTA solution. Under fluidic conditions using an antibody-modified micropost chip, the cells were mainly captured on the micropost walls of the chip rather than on the bottom of it. The presented method will also be applicable for immobilization of oriented antibodies on various microfluidic chips with different structures.