Measurement of the extent of electron transfer to the bacteriopheophytin in the M-subunit in reaction centers of Rhodopseudomonas viridis

We have measured the extent of flash-induced electron transfer from the bacteriochlorophyll dimer, P, to the bacteriopheophytin in the M-subunit, H_M, in reaction centers of Rhodopseudomonas viridis. This has been done by measuring the transient states produced by excitation of reaction centers trapped in the PH_L ^–H_M state at 90 K. Under these conditions the normal forward electron transfer to the bacteriopheophytin in the L-subunit, H_L, is blocked and the yield of transient P⁺H_M ^– can be estimated with respect to the lifetime of P^*. Under these conditions flash induced absorbance decreases of the bacteriochlorophyll dimer 990 nm band suggest that a transient P⁺ state is formed with a quantum yield of 0.09±0.06 compared to that formed during normal photochemistry. These transient measurements provide an upper limited on the yield of a transient P⁺ H_M ^– state. An estimate of 0.09 as the yield of the P⁺ H_M ^– state is consistent with all current observations. This estimate and the lifetime of P^* suggest that the electron transfer rate from P^* to H_M, k_M, is about 5 × 10⁹ sec^–1 (_M = 200ps). These measurements suggest that the a branching ratio k_L/k_M is on the order of 200. The large value of the branching ratio is remarkable in view of the structural symmetry of the reaction center. This measurement should be useful for electron transfer calculations based upon the reaction center structure.     

Effect of reduction of the reaction center intermediate upon the picosecond oxidation reaction of the bacteriochlorophyll dimer in Chromatium vinosum and Rhodopseudomonas viridis

The photo-oxidation of the reaction center bacteriochlorophyll dimer or special pair was monitored at 1235 nm in Chromatium vinosum and at 1301 nm in Rhodopseudomonas viridis. In both species, the photo-oxidation was apparently complete within 10 ps after light excitation and proceeded unimpeded at low temperatures regardless of the prior state of reduction of the traditional primary electron acceptor, a quinone-iron complex. Thus the requirement for an intermediary electron carrier (I), previously established by picosecond measurements in Rps. sphaeroides (see ref. 4), is clearly a more general phenomenon.

The intermediary carrier, which involves bacteriopheophytin, was examined from the standpoint of its role as the direct electron acceptor from the photo-excited reaction center bacteriochlorophyll dimer. To accomplish this, the extent of light induced bacteriochlorophyll dimer oxidation was measured directly by the picosecond response of the infrared bands and indirectly by EPR assay of the triplet/biradical, as a function of the state of reduction of the I/I couple (measured by EPR) prior to activation. Two independent methods of obtaining I in a stably reduced form were used: chemical equilibrium reduction, and photochemical reduction. In both cases, the results demonstrated that the intermediary carrier, which we designate I, alone governs the capability for reaction center bacteriochlorophyll photooxidation, and as such I appears to be the immediate and sole electron acceptor from the light excited reaction center bacteriochlorophyll dimer.     

Spectroscopic properties of the intermediary electron carrier in the reaction center of Rhodopseudomonas viridis evidence for its interaction with the primary acceptor

The spectroscopic properties of the intermediary electron carrier (I), which functions between the bacteriochlorophyll dimer, (BChl)₂, and the primary acceptor quinone · iron, QFe, have been characterized in Rhodopseudomonas viridis. Optically the reduction of I is accompanied by a bleaching of bands at 545 and 790 nm and a broad absorbance increase around 680 nm which we attribute to the reduction of a bacteriopheophytin, together with apparent blue shifts of the bacteriochlorophyll bands at 830 and possibly at 960 nm. Low temperature electron paramagnetic resonance analysis also reveals complicated changes accompanying the reduction of I. In chromatophores I? is revealed as a broad split signal centered close to g 2.003, which is consistent with I? interacting, via exchange coupling and dipolar effects, with the primary acceptor Q?Fe. This is supported by experiments with reaction centers prepared with sodium dodecyl sulfate, which lack the Q?Fe g 1.82 signal, and also lack the broad split I? signal; instead, I? is revealed as an approximately 13 gauss wide free radical centered close to g 2.003. Reaction centers prepared using lauryl dimethylamine N-oxide retain most of their Q?Fe g 1.82 signal, and in this case I? occurs as a mixture of the two EPR signals described above. However, the optical changes accompanying the reduction of I? are very similar in the two reaction center preparations, so we conclude that there is no direct correlation between the two optical and the two EPR signals of I?. Perhaps the simplest explanation of the results is that the two EPR signals reflect the reduced bacteriopheophytin either interacting, or not interacting, with Q?Fe, while the optical changes reflect the reduction of bacteriophenophytin, together with secondary, perhaps electrochromic effects on the bacteriochlorophylls of the reaction center. However, we are unable to eliminate completely the possibility that there is also some electron sharing between the reduced bacteriopheophytin and bacteriochlorophyll.     

Metabolic activation of hexamethylmelamine and pentamethylmelamine by liver microsomal preparations

Incubation of [¹⁴C]-ring labeled hexamethylmelamine and pentamethylmelamine with rat and mouse liver microsomal preparations results in metabolic activation of both drugs as measured by covalent binding of radiolabel to acid-precipitable microsomal macromolecules. Covalent binding is dependent on viable microsomes, NADPH, and molecular oxygen. Binding of HMM (280 pmol/mg protein/15 min) was approximately 5 times greater than that observed for PMM (60 pmol/mg protein/15 min), and represents 0.22% of incubated material. Similar results were found with [¹⁴C]-methyl labeled substrates. Pretreatment with phenobarbital increased covalent binding while addition of SKF 525-A, addition of glutathione, or incubation in an 80% carbon monoxide atmosphere reduced covalent binding.     

EPR and optical spectroscopic properties of the electron carrier intermediate between the reaction center bacteriochlorophylls and the primary acceptor in Chromatium vinosum.

1. A reaction center-cytochrome c complex has been isolated from Chromatium vinosum which is capable of normal photochemistry and light-activated rapid cytochrome c553 and c555 oxidation, but which has no antenna bacteriochlorophyll. As is found in whole cells, ferrocytochrome c553 is oxidized irreversibly in milliseconds by light at 7 K. 2. Room temperature redox potentiometry in combination with EPR analysis at 7 K, of cytochrome c553 and the reaction center bacteriochlorophyll dimer (BChl)2 absorbing at 883 nm yields identical results to those previously reported using optical analytical techniques at 77 K. It shows directly that two cytochrome c553 hemes are equivalent with respect to the light induced (BChl)2+. At 7 K, only one heme can be rapidly oxidized in the light, commensurate with the electron capacity of the primary acceptor (quinone-iron) being unity. 3. Prior chemical reduction of the quinone-iron followed by illumination at 200K, however, leads to the slow (t1/2 approximately equal to 30 s) oxidation of one cytochrome c553 heme, with what appears to be concommitant reduction of one of the two bacteriophytins (BPh) of the reaction center as shown by bleaching of the 760 nm band, a broad absorbance increase at approx. 650 nm and a bleaching at 543 nm. The 800 nm absorbing bacteriochlorophyll is also involved since there is also bleaching at 595 and 800 nm; at the latter wave-length the remaining unbleached band appears to shift significantly to the blue. No redox changes in the 883 absorbing bacteriochlorophyll dimer are seen during or after illumination under these conditions. The reduced part of the state represents what is considered to be the reduced form of the electron carrier (I) which acts as an intermediate between the bacteriochlorophyll dimer and quinone-iron. The state (oxidized c553/reduced I) relaxes in the dark at 200K in t1/2 approx. 20 min but below 77 K it is trapped on a days time scale. 4. EPR analysis of the state trapped as described above reveals that one heme equivalent of cytochrome becomes oxidized for the generation of the state, a result in agreement with the optical data. Two prominent signals are associated with the trapped state in the g = 2 region, which can be easily resolved with temperature and microwave power saturation: one has a line width of 15 g and is centered at g = 2.003; the other, which is the major signal, is also a radical centered at g = 2.003 but is split by 60 G and behaves as though it were an organic free-radical spin-coupled with another paramagnetic center absorbing at higher magnetic field values; this high field partner could be the iron-quinone of the primary acceptor. The identity of two signals associated with I-. is consistent with the idea that the reduced intermediary carrier is not simply BPh-. but also involves a second radical, perhaps the 800 nm bacteriochlorophylls in the reduced state...     

Beyond tumorigenesis： cancer stem cells in metastasis

The importance of cancer stem cells （CSCs） in tumor-initiation has been firmly established in leukemia and recently reported for a variety of solid tumors. However, the role of CSCs in multistage cancer progression, particularly with respect to metastasis, has not been well-defined. Cancer metastasis requires the seeding and successful colonization of specialized CSCs at distant organs. The biology of normal stem cells and CSCs share remarkable similarities and may have important implications when applied to the study of cancer metastasis. Furthermore, overlapping sets of molecules and pathways have recently been identified to regulate both stem cell migration and cancer metastasis. These molecules constitute a complex network of cellular interactions that facilitate both the initiation of the pre-metastasis niche by the primary tumor and the formation of a nurturing organ microenvironment for migrating CSCs. In this review, we surveyed the recent advances in this dynamic field and propose a unified model of cancer progression in which CSCs assume a central role in both tumorigenesis and metastasis. Better understanding of CSCs as a fundamental component of the metastatic cascade will lead to novel therapeutic strategies against metastatic cancer.     

Engineering a circularly permuted GFP scaffold for peptide presentation

The use of peptides as in vivo and in vitro ligand binding agents is hampered by the high flexibility, low stability and lack of intrinsic detection signal of peptide aptamers. Recent attempts to overcome these limitations included the integration of the binding peptide into a stable protein scaffold. In this paper, we present the optimization and testing of a circularly permuted variant of the green fluorescent protein (GFP). We examined the ability of the optimized scaffold to accept peptide insertions at three different regions. The three regions chosen are localized in close spatial proximity to each other and support different conformations of the inserted peptides. In all the three regions peptides with a biased, but still comprehensive, amino acid repertoire could be presented without disturbing the function of the optimized GFP-scaffold.     

From milk to malignancy: the role of mammary stem cells in development, pregnancy and breast cancer

Adult stem cells of the mammary gland (MaSCs) are a highly dynamic population of cells that are responsible for the generation of the gland during puberty and its expansion during pregnancy. In recent years significant advances have been made in understanding how these cells are regulated during these developmentally important processes both in humans and in mice. Understanding how MaSCs are regulated is becoming a particularly important area of research, given that they may be particularly susceptible targets for transformation in breast cancer. Here, we summarize the identification of MaSCs, how they are regulated and the evidence for their serving as the origins of breast cancer. In particular, we focus on how changes in MaSC populations may explain both the increased risk of developing aggressive ER/PR(-) breast cancer shortly after pregnancy and the long-term decreased risk of developing ER/PR(+) tumors.     

Structural studies of the manganese stabilizing subunit in photosystem II

Photosystem II (PSII) is the plant photosynthetic reaction center that carries out the light driven oxidation of water. The water splitting reactions are catalyzed at a tetranuclear manganese cluster. The manganese stabilizing protein (MSP) of PSII stabilizes the manganese cluster and accelerates the rate of oxygen evolution. MSP can be removed from PSII, with an accompanying decrease in activity. Either an Escherichia coli expressed version of MSP or native, plant MSP can be rebound to the PSII reaction center; MSP reconstitution reverses the deleterious effects associated with MSP removal. We have employed Fourier transform infrared (FTIR) spectroscopy and solution small angle x-ray scattering (SAXS) techniques to investigate the structure of MSP in solution and to define the structural changes that occur before and after reconstitution to PSII. FTIR and SAXS are complementary, because FTIR spectroscopy detects changes in MSP secondary structure and SAXS detects changes in MSP size/shape. From the SAXS data, we conclude that the size/shape and domain structure of MSP do not change when MSP binds to PSII. From FTIR data acquired before and after reconstitution, we conclude that the reconstitution-induced increase in beta-sheet content, which was previously reported, persists after MSP is removed from the PSII reaction center. However, the secondary structural change in MSP is metastable after removal from PSII, which indicates that this form of MSP is not the lowest energy conformation in solution.