[Edited for grammar.]
Sorry for the delayed reply: I typed this up yesterday afternoon, but got called away before I could post it.
I'm afraid I might have misled you with my question. With 10 degree spacing, you should have 18 rings with 36 samples each; otherwise, half your data points would be duplicates (possible, but unlikely).
You can make a wire plot as you described using plot3, though it takes a little finessing since Matlab uses phi as elevation from the x-axis instead of z-, and ultimately, might not be very useful.
I'll construct some dummy data and show three plot types you might wish to consider.
dtr = pi/180;
th = [0:10:180].'*dtr;
phi = [0:10:360].'*dtr + 90*dtr;
r = 1;
[TH, PHI, R] = meshgrid(th, phi, r);
f = @(th, phi, r) r.*sin(2*th).*cos(4*phi);
data = f(TH, PHI, R);
meshgrid takes the vectors specified by theta, phi, and r and creates 3-D arrays, suitable for plotting; however, since r only has a single value equal to one, the arrays are equivalent to matrices, i.e. m-by-n-by-1. Also, since Matlab's version of spherical coordinates uses phi to denote elevation from the x-axis, not the z-axis, we've added 90-degrees to phi to better replicate your example plot.
(Note that I'm assuming you already have data, so you won't need to define the anonymous function f, and that your data is in the form of a 36-by-18 matrix; my examples are size 37-by-19, because I've duplicated the point at the pole [this is to prevent holes in the surface plot]; you might need to pad your data using something like data = [data(end, :); data]; data = [data(:, end), data];, which prepends the original matrix with its own last column and row.)
Note that the data is in spherical coordinates, but Matlab can really only plot cartesian in 3-D. To generate the plot data, we can use sph2cart:
[X, Y, Z] = sph2cart(TH, PHI, R);
The first method we'll look at uses plot3 and recreates the wireframe you showed. Unfortunately, the entire line object must be a solid color (unless the newer version of Matlab has added a new feature), so it won't be terribly useful for displaying the intensity.
figure;
axes;
plot3(X(:), Y(:), Z(:));
You can add some formatting to make it look more like your example (search the help docs to understand what these commands are doing):
grid('on')
set(gca, 'Ztick', [])
set(gca, 'XMinorGrid', 'on')
set(gca, 'YMinorGrid', 'on')
axis('equal');
axis('square');
xlabel('x')
ylabel('y')
zlabel('z')
title('plot3')
The above reasonably reproduces your example, but isn't terribly useful since it doesn't make use of the data.
To plot just the data points you actually measured, try scatter3:
figure;
axes;
scatter3(X(:), Y(:), Z(:), 15, data(:), 'filled');
grid('on')
set(gca, 'Ztick', [])
set(gca, 'XMinorGrid', 'on')
set(gca, 'YMinorGrid', 'on')
axis('equal');
axis('square');
xlabel('x')
ylabel('y')
zlabel('z')
title('scatter3')
Finally, consider using a surface plot:
figure;
axes;
surf(X, Y, Z, data);
grid('on')
set(gca, 'Ztick', [])
set(gca, 'XMinorGrid', 'on')
set(gca, 'YMinorGrid', 'on')
axis('equal');
axis('square');
xlabel('x')
ylabel('y')
zlabel('z')
title('surf')
If you want, you can use shading to interpolate the data, instead of the having a patch-work quilt, but interpolation may introduce artifacts into the representation of your data:
There's a lot of options above. Search the help docs for anything you don't understand, and feel free to ask another question if you're struggling with anything. (And please accept this answer if it helps.)
