Ramírez-Gómez HV , Jimenez Sabinina V , Velázquez Pérez M , Beltran C , Carneiro J , Wood CD , Tuval I , Darszon A , Guerrero A .

Fronteras 71 Consejo Nacional de Ciencia y Tecnología, Ciencia basica 252213 y 255914 Consejo Nacional de Ciencia y Tecnología, IA202417 Dirección General de Asuntos del Personal Académico, Universidad Nacional Autónoma de México, IN205516 Dirección General de Asuntos del Personal Académico, Universidad Nacional Autónoma de México, IN206016 Dirección General de Asuntos del Personal Académico, Universidad Nacional Autónoma de México, IN215519 Dirección General de Asuntos del Personal Académico, Universidad Nacional Autónoma de México, IN112514 Dirección General de Asuntos del Personal Académico, Universidad Nacional Autónoma de México, FIS2013-48444-C2-1-P Ministerio de Economía y Competitividad, FIS2016-77692-C2-1- P Ministerio de Economía y Competitividad, JSPS/236, ID no. S16172 Japan Society for the Promotion of Science , Fronteras 71,Ciencia basica 252213 y 255914 Consejo Nacional de Ciencia y Tecnología, IA202417,IN205516,IN206016,IN215519 and IN112514 Dirección General de Asuntos del Personal Académico, Universidad Nacional Autónoma de México, FIS2013-48444-C2-1-P,FIS2016-77692-C2-1- P Ministerio de Economía y Competitividad

	Figure 1—figure supplement 1. Chemoattractant diffusive currents have a non-linear relationship to receptor coverage.For a spherical cell of radius a, with N disk-like receptors of effective radius s, the diffusive current saturates for N >> N1/2 = πa⁄s (N1/2 is highlighted for S. purpuratus, L. pictus and A. punctulata with a green, blue and black dots, respectively). For S. purpuratus, however, the number of receptors is smaller than N1/2 and the diffusive influx falls into an almost linear regime.
	Figure 1. Physics of chemoreception.(a) A spermatozoon swimming in an isotropic chemoattractant concentration field, where the number of molecules detected (n) is within the noise of detection. (b) A spermatozoon swimming near to an egg, while chemoattractant molecules are diffusing from its surrounding jelly layer creating a chemoattractant gradient. Note that the signal detected in this case is larger than the detection noise. (c) The assessment of a chemoattractant concentration gradient requires that the signal difference ∂c between two sampled positions ∂r must be greater than the noise. (d–f) The signal-to-noise ratio in the determination of the chemoattractant gradient SNR plotted against the relative slope of the chemoattractant concentration gradient in log scale, ξ=c--1∂c∂r, for different chemoattractant concentrations of speract for either S. purpuratus (d), or L. pictus (e) spermatozoa, and of resact for A. punctulata (f) spermatozoa (see Supplementary file 1 for the list of parameter values taken in consideration for panels d–f). S. purpuratus spermatozoa have lower capacity of detection for the same chemoattractant concentrations at a given ξ than L. pictus and A. punctulata. The tone of the shaded areas indicates shallow or steep gradient conditions. The horizontal dotted line represents SNR = 1; the vertical magenta line represents ξ = 2.6 x 10−3 µm−1. Colors of the line traces (from blue to brown) indicate distinct chemoattractant concentrations in the range [10−6 – 10−11 M].
	Figure 2. Screening of speract concentration gradients.(a) Radial profile and its derivative (b) of the UV light scattered at the glass-liquid interface for each optical fiber (f1–f5). (c) Spatial distribution of the UV flash energy for each fiber. (d) Representative motility and [Ca2+]i responses of S. purpuratus spermatozoa exposed to different concentration gradients of speract. F-F0 time projections, showing spermatozoa head fluorescence at 3 s intervals before and after photoactivation of 10 nM caged speract in artificial seawater with 200 ms UV flash. The pseudo-color scale represents the relative fluorescence of fluo-4, a [Ca2+]i indicator, showing maximum (red) and minimum (blue) relative [Ca2+]i. Scale bars of 50 µm.
	Figure 3—figure supplement 1. Automatic segmentation of swimming spermatozoa.Work-flow of the segmentation algorithm: Video microscopy images were background subtracted by removing the temporal average intensity projection (static fraction) of the un-stimulated frames (93 frames = 3 s), from the whole video (25 s). The resulting images were convolved with a low-pass spatial frequency filter to reduce noise (detector, electronic, shot). The resulting images were thresholded to generate arrays of regions of interest (ROIs), a heuristic search for connected components was then applied to label single ROIs and to assign the corresponding pixels to unique spermatozoa. Scale bar of 15 µm.
	Figure 3—figure supplement 2. Sperm response to speract photo-release, collated data from individual experiments.Sperm motility responses to different speract concentration gradients (f1, f2, f3, f4, f5) at R1 (a), R2 (b), R3 (c) and R4 (d) concentric regions (see Figure 3a). Negative controls for sperm chemotaxis are artificial sea water with nominal 0 Ca2+ (Low Ca2+); and artificial sea water with 40 mM of K+ (High K+). Each time trace represents the mean sperm density from up to 20 video microscopy experiments. Note that peak responses occurred around 6 s (shown by the vertical dashed lines), some 3 s after speract exposure (indicated as vertical dotted lines). Purple vertical line indicates the UV flash (200 ms).
	Figure 3—figure supplement 3. Spontaneous vs. speract-induced [Ca2+]i oscillations.(a) Example of a spontaneous Ca2+ oscillation (two oscillations). Only 20% of sperm experiencing spontaneous oscillations suffer more than one oscillation, most of them experience only one [Ca2+]i increase. (b) Representative trace of speract-induced oscillations. Caged-speract was released after third second. (c) Comparison of Ca2+ oscillation amplitude between spontaneous (blue) vs. speract-induced (red) oscillations. n = 75 for spontaneous and n = 56 for speract-induced oscillations. (d) Comparison of Ca2+ oscillation period between spontaneous (blue) vs. speract-induced (red) oscillations. n = 16 for spontaneous and n = 56 for speract-induced oscillations. *Statistical significance, p<0.01, Mann-Whitney U test. [Ca2+]i oscillation traces (panels a and b) were smoothed using an average filter with a four frame window in a 30.8 fps setting. For further information see Extended Materials and methods, section 2.8. Spontaneous vs. speract-induced [Ca2+]i oscillations.
	Figure 3. Motility and [Ca2+]i responses of S. purpuratus spermatozoa exposed to specific concentration gradients of speract.(a) The positions of the sperm heads within the imaging field are automatically assigned to either R1, R2, R3 or R4 concentric regions around the centroid of the UV flash intensity distribution. Each ROI was also used to obtain the sperm head fluorescence from the raw video microscopy images (as the mean value of the ROI) (see Figure 3—figure supplement 1). Scale bar of 50 µm. (b) Fold change in sperm number, defined as the number of spermatozoa at the peak of the response (6 s) relative to the mean number before speract stimulation (0–3 s) (see Figure 3—figure supplement 2). (c) Relative changes in [Ca2+]i experienced by spermatozoa at the peak response (6 s) after speract stimulation. Negative controls for spermatozoa chemotaxis are artificial seawater with nominal Ca2+ (Low Ca2+); and artificial seawater with 40 mM of K+ (High K+). Both experimental conditions prevent chemotactic responses by inhibiting the Ca2+ membrane permeability alterations triggered by speract; the former disrupts the Ca2+ electrochemical gradient, and the later disrupt the K+ electrochemical gradient required as electromotive force needed to elevate pHi, and to open Ca2+ channels. The central line in each box plot represents the median value, the box denotes the data spread from 25% to 75%, and the whiskers reflect 10–90%. The number of experiments is indicated on the bottom of each experimental condition. We used the same number of experiments for the relative change in [Ca2+]i (right panel). *Statistical significance, p<0.05; multiple comparison test after Kruskal-Wallis.
	Figure 4—figure supplement 1. Sperm swimming behavior in response to different chemoattractant gradients.S. purpuratus sperm behavior classified in four different classes: i) No response (purple), when spermatozoa keep swimming in concentric circles and do not move more than 15 µm of progressive swimming; ii) Toward the chemoattractant source (cyan), when spermatozoa respond drifting in swimming circles with an orientation angle (θ) smaller than 60° (θ < 60°); iii) Opposite to the chemoattractant source (pink), when spermatozoa respond drifting in swimming circles with an orientation angle (θ) bigger than 120° (θ > 120°); and iv) Perpendicular to the chemoattractant source (green), when spermatozoa respond drifting in swimming circles with an orientation angle (θ) smaller than 120° but bigger than 60° (60° ≤ θ ≤ 120°). The orientation angle θ is defined as the swimming angle of the drifting circles after speract uncaging (see Figure 4b). This analysis was made at second six after speract uncaging. Numbers in each bar represent the number of spermatozoa in each condition. Inset at the right panel shows the orientation angles (θ). For further information see Extended Materials and methods, section 2.7. Sperm swimming behavior in different chemoattractant gradients.
	Figure 4. S. purpuratus spermatozoa selectively experience chemotaxis toward specific speract gradients.(a) Sperm trajectory before (gray) and after (black) the UV irradiation (purple). (b) Definition of a chemotactic index to score chemotactic responses. Dots represent sperm trajectory before (gray) and after (black) UV irradiation. Green and blue empty spirals indicate the smoothed trajectory before and after UV irradiation. Gray and black vectors are the progressive sperm displacement before and after stimulation, respectively; and the v and u vectors are the linear speed before and after stimulation; and ϕ and θ are the angles to their corresponding reference vectors to the center of the imaging field – the highest UV irradiated area, (magenta and red, respectively). Chemotactic index (CI) is defined as in the inset (see also Video 2). (c) Temporal evolution of the chemotactic index. Functions were calculated from the median obtained from sperm trajectories of each of f1, f2, f3, f4, f5, f2-ZeroCa2+, and f2-HighK+ experimental conditions (Appendix 1—video 7). (d) Radial histograms of CI computed at second 9 (vertical dotted line at panel c). Significant differences (Binomial test, p-value<0.05) were observed only for f2, f3 and f5 fibers, compared to controls. n represents the number of individual sperm trajectories analyzed. (e) CI as a function of the signal-to-noise ratio (SNR). Each parameter was calculated for single cells. Large filled points represent the median for each gradient condition distribution. (f) Fraction of responding cells as a function of the SNR (spermatozoa whose effective displacement was above the unstimulated cells). The apparent diffusion of the swimming drifting circle of unstimulated S. purpuratus spermatozoa is Dapp = 9 ± 3 µm2 s−1 (Friedrich, 2008; Friedrich and Jülicher, 2008; Riedel et al., 2005), here responsive cells were considered by showing a Dapp = 9 µm2 s−1, and were evaluated at second 9.
	Figure 5—figure supplement 1. Modeling of the dynamics of speract gradient based on the UV light profile of distinct optical fibers.The radial profiles of the UV light scattered at the glass-liquid interface of f1, f3, f4, f5 optical fibers are shown in gray. The speract gradient was generated as in Figure 5, but with the corresponding f1 (a and b), f3 (c and d), f4 (e and f) and f5 (g and h) optical fibers. Left panels - The dynamics of the speract gradient computed as is in Figure 5. The blue dashed line (t0 = 0) corresponds to a Gaussian distribution fitted to the UV light profile, and illustrates the putative shape of the instantaneously generated speract gradient. Solid black lines illustrate the shape of the speract gradient after t = 1, 2, 3, …, 20 s. Right panels - Simulated temporal changes in speract concentration gradients of f1 (a), f3 (c), f4 (e) and f5 (g) at each 10 µm radial point from the center of the concentration gradient.
	Figure 5—figure supplement 2. Characteristic motility changes of a S. purpuratus spermatozoon exposed to f3 and f4 speract gradients (chemotactic vs. non-chemotactic response).Panels (a and b) show single cell responses to the f3 speract gradient (chemotactic); and panels c) and d) to the f4 speract gradient (non-chemotactic). (a, c) Solid lines illustrate the spermatozoon swimming trajectory 3 s before (gray) and 6 s after (black) speract gradient exposure. (b, d). Stimulus function computed from (a and c), considering the spatio-temporal dynamics of speract computed for the f3 and f4 gradients, respectively.
	Figure 5. Steep speract gradients provoke chemotaxis in S. purpuratus spermatozoa. a.Dynamics of the f2 speract gradient. The blue dashed line (t0 = 0 s) corresponds to a Gaussian distribution fitted to the UV light profile and illustrates the putative shape of the instantaneously-generated speract concentration gradient. Solid black lines illustrate the temporal evolution of the speract concentration field after t = 1, 2, 3, …, 20 s. (b) Temporal changes in the f2 speract field computed radially (each 10 µm) from the center of the gradient. (c) Characteristic motility changes of a S. purpuratus spermatozoon exposed to the f2 speract gradient. Solid lines illustrate its swimming trajectory 3 s before (gray), during UV flash (purple) and 6 s after (black) speract exposure. (d) Spermatozoa head distance to the source of the speract gradient versus time, calculated from sperm trajectory in (c). (e). Stimulus function computed from the swimming behavior of the spermatozoon in (c), considering the dynamics of (a and b).
	Figure 6—figure supplement 1. Speract induces Ca2+ oscillations in immobilized S. purpuratus spermatozoa.Spermatozoa were immobilized on cover slips coated with poly-D-lysine (see Materials and methods), and ASW containing 500 nM caged speract added. Recordings were performed 3 s before and during 6 s after 200 ms of UV irradiation. f4 optical fiber was used for the UV light path, to generate the speract concentration gradient. Time traces indicate the [Ca2+]i of selected spermatozoa of Appendix 1—video 8. Note that the photo-release of speract induces a train of [Ca2+]i increases in immobilized spermatozoa, and hence provides evidence for the presence of an internal Ca2+ oscillator triggered by speract.
	Figure 6—figure supplement 2. Cross-correlation analysis of [Ca2+]i and stimulus function derivative (dS) signals.Representative examples of [Ca2+]i (red) and the derivative of the stimulus function (dS) (black) were plotted and then analyzed by cross-correlation analysis (CCF). Red vertical lines indicate the zero, blue vertical lines indicate the point of maximum correlation for each case, which means that the phase shifting between [Ca2+]i and dS is around 200 ms in these cases. Examples of a pair of spermatozoa for the two principal chemotactic gradients (f2 and f3) are shown. (a, b) Representative examples of two spermatozoa in an f2 gradient. (c, d) Representative examples of two spermatozoa in an f3 gradient.
	Figure 6. The slope of the speract concentration gradient generates a frequency-locking phenomenon between the stimulus function and the internal Ca2+ oscillator triggered by speract.(a) Coupled oscillator model. Each sperm has two independent oscillators: i) stimulus function and ii) [Ca2+]i, which can be coupled through a forcing term that connects them, in our case the slope of the chemoattractant concentration gradient (ξ0). (b) Maximum relative slopes (ξmax) of the chemoattractant concentration gradient experienced by S. purpuratus (Sp) spermatozoa when exposed to f1, f2, f3, f4, f5 speract gradients. The maximum relative slopes of the chemoattractant concentration gradient experienced by L. pictus spermatozoa (Lp) toward f4 experimental regime are also shown. Note that ξmax for f2, f3, and f5, are up to 2–3 times greater than in f4, regardless of the species. (c) Experimental signal-to-noise ratios (SNR) regimes experienced by spermatozoa swimming in different gradient conditions. Note that only f2, f3 and f5 have higher SNR, compared to other gradient conditions, for which stochastic fluctuations mask the signal. This SNR calculation assumes a 10% of speract uncaging. The maximum relative slopes (ξ) are shown in log scale (d) Arnold’s tongue indicating the difference in intrinsic frequency of the internal Ca2+ oscillator of S. purpuratus spermatozoa, just before and after the speract gradient exposure. (e). Phase difference between the time derivative of the stimulus function and the internal Ca2+ oscillator of S. purpuratus spermatozoa, obtained by computing the cross-correlation function between both time series (Figure 6—figure supplement 2). (f). Phase difference between the time derivative of the stimulus function and the internal Ca2+ oscillator of S. purpuratus spermatozoa expressed in temporal delays. (d-f) Gray points represent the collated data of all f1, f2, f3, f4, f5 experimental regimes. Red, black and blue points indicate chemotactic spermatozoa (CI > 0 at second three after UV flash), located in R3, and R4 regions just before the speract gradient is established under f2, f3 and f5 experimental regimes, respectively. Magenta lines represent the transition boundary (γmin = ξmax∗¯ ~ 2.6×10−3 µm−1, see also Figure 1d–f) below which no synchrony is observed, obtained from the theoretical estimates (black curves, mean of Δω) of panels (e) and (f). Green dashed lines indicate confidence intervals (mean ± standard deviation).
	Author response image 1. Diffusion solutions in 1 dimension (1D) and 2 dimensions (2D).Diffusion simulation in 1D (a,b) and 2D (c,d) and the estimated relative error percentage between 1D and 2D (f). The numerical solution for the time dependent diffusion equation (i.e. the concentration profiles) for 1D and 2D, respectively, is shown in (a) and (c). The initial profile set at the time when the chemoattractant was activated with a UV flash (t = 3s) is highlighted as a blue dash line. Time evolution is shown in 1s intervals up to t = 10s (black lines). (b and d) depict the relative gradients (i.e. normalized derivatives) of the chemoattractant concentration. Black and red solid points indicate their spatial average at each time step, which in panel (e) is plotted as a function of time. In (f), the error percentage between 1D and 2D models was computed as (2D-1D)/1D from panel (e), and its temporal average is marked by a black solid point that indicates that the mean error between the 1D and 2D diffusion models for a typical chemotactic trajectory is about 25%.

Aguilera, What is the core oscillator in the speract-activated pathway of the Strongylocentrotus purpuratus sperm flagellum? 2012, Pubmed, Echinobase

Aguilera, What is the core oscillator in the speract-activated pathway of the Strongylocentrotus purpuratus sperm flagellum? 2012, Pubmed , Echinobase
Alvarez, The rate of change in Ca(2+) concentration controls sperm chemotaxis. 2012, Pubmed , Echinobase
Amselem, Control parameter description of eukaryotic chemotaxis. 2012, Pubmed
Beltrán, Zn(2+) induces hyperpolarization by activation of a K(+) channel and increases intracellular Ca(2+) and pH in sea urchin spermatozoa. 2014, Pubmed , Echinobase
Berg, Physics of chemoreception. 1977, Pubmed
Brokaw, Calcium-induced asymmetrical beating of triton-demembranated sea urchin sperm flagella. 1979, Pubmed , Echinobase
Böhmer, Ca2+ spikes in the flagellum control chemotactic behavior of sperm. 2005, Pubmed , Echinobase
Cook, Sperm chemotaxis: egg peptides control cytosolic calcium to regulate flagellar responses. 1994, Pubmed , Echinobase
Darszon, Sperm-activating peptides in the regulation of ion fluxes, signal transduction and motility. 2008, Pubmed , Echinobase
Espinal, Discrete dynamics model for the speract-activated Ca2+ signaling network relevant to sperm motility. 2011, Pubmed , Echinobase
Friedrich, Steering chiral swimmers along noisy helical paths. 2009, Pubmed
Friedrich, Chemotaxis of sperm cells. 2007, Pubmed
Friedrich, Search along persistent random walks. 2008, Pubmed
Garcés, Automatic detection and measurement of viral replication compartments by ellipse adjustment. 2016, Pubmed
Guerrero, Niflumic acid disrupts marine spermatozoan chemotaxis without impairing the spatiotemporal detection of chemoattractant gradients. 2013, Pubmed , Echinobase
Guerrero, Tuning sperm chemotaxis by calcium burst timing. 2010, Pubmed , Echinobase
Guerrero, Tuning sperm chemotaxis. 2010, Pubmed , Echinobase
Hansbrough, Speract. Purification and characterization of a peptide associated with eggs that activates spermatozoa. 1981, Pubmed , Echinobase
Hussain, Individual female differences in chemoattractant production change the scale of sea urchin gamete interactions. 2017, Pubmed , Echinobase
Jikeli, Sperm navigation along helical paths in 3D chemoattractant landscapes. 2015, Pubmed , Echinobase
Kashikar, Temporal sampling, resetting, and adaptation orchestrate gradient sensing in sperm. 2012, Pubmed , Echinobase
Kaupp, The signal flow and motor response controling chemotaxis of sea urchin sperm. 2003, Pubmed , Echinobase
Kaupp, 100 years of sperm chemotaxis. 2012, Pubmed
Kromer, Decision making improves sperm chemotaxis in the presence of noise. 2018, Pubmed , Echinobase
Lazova, Response rescaling in bacterial chemotaxis. 2011, Pubmed
Lillie, THE MECHANISM OF FERTILIZATION. 1913, Pubmed
Mead, The effects of hydrodynamic shear stress on fertilization and early development of the purple sea urchin Strongylocentrotus purpuratus. 1995, Pubmed , Echinobase
Meijering, Methods for cell and particle tracking. 2012, Pubmed
Mizuno, Calaxin establishes basal body orientation and coordinates movement of monocilia in sea urchin embryos. 2017, Pubmed , Echinobase
Nishigaki, Time-resolved sperm responses to an egg peptide measured by stopped-flow fluorometry. 2001, Pubmed , Echinobase
Nishigaki, A sea urchin egg jelly peptide induces a cGMP-mediated decrease in sperm intracellular Ca(2+) before its increase. 2004, Pubmed , Echinobase
Nishigaki, Real-time measurements of the interactions between fluorescent speract and its sperm receptor. 2000, Pubmed , Echinobase
Nosrati, Two-dimensional slither swimming of sperm within a micrometre of a surface. 2015, Pubmed
Pichlo, High density and ligand affinity confer ultrasensitive signal detection by a guanylyl cyclase chemoreceptor. 2014, Pubmed , Echinobase
Riedel, A self-organized vortex array of hydrodynamically entrained sperm cells. 2005, Pubmed , Echinobase
Riffell, Sex and flow: the consequences of fluid shear for sperm-egg interactions. 2007, Pubmed
Schneider, NIH Image to ImageJ: 25 years of image analysis. 2012, Pubmed
Shiba, Ca2+ bursts occur around a local minimal concentration of attractant and trigger sperm chemotactic response. 2008, Pubmed
Solzin, Revisiting the role of H+ in chemotactic signaling of sperm. 2004, Pubmed , Echinobase
Strünker, A K+-selective cGMP-gated ion channel controls chemosensation of sperm. 2006, Pubmed , Echinobase
Strünker, At the physical limit - chemosensation in sperm. 2015, Pubmed , Echinobase
Suzuki, Structure, function and biosynthesis of sperm-activating peptides and fucose sulfate glycoconjugate in the extracellular coat of sea urchin eggs. 1995, Pubmed , Echinobase
Tatsu, A caged sperm-activating peptide that has a photocleavable protecting group on the backbone amide. 2002, Pubmed , Echinobase
Vergassola, 'Infotaxis' as a strategy for searching without gradients. 2007, Pubmed
Wood, Speract induces calcium oscillations in the sperm tail. 2003, Pubmed , Echinobase
Wood, Altering the speract-induced ion permeability changes that generate flagellar Ca2+ spikes regulates their kinetics and sea urchin sperm motility. 2007, Pubmed , Echinobase
Wood, Real-time analysis of the role of Ca(2+) in flagellar movement and motility in single sea urchin sperm. 2005, Pubmed , Echinobase
Yoshida, Sperm chemotaxis and regulation of flagellar movement by Ca2+. 2011, Pubmed
Zimmer, Sperm chemotaxis, fluid shear, and the evolution of sexual reproduction. 2011, Pubmed