No. On  $\mathbb P^1=\mathbb P^1(\mathbb C)$ we have $\Gamma(\mathbb P^1,\mathcal O_{\mathbb P^1}(-1))=\Gamma(\mathbb P^1,\mathcal O_{\mathbb P^1}(-2)=0$, but $O_{\mathbb P^1}(-1)$ and $O_{\mathbb P^1}(-2)$ are not isomorphic.  
   
However on an *affine algebraic* variety $X$, the answer is "yes". There is an amazing equivalence of categories between $\mathcal O(X)$-modules and the so-called quasi coherent sheaves on $X$. It is denoted  $M\mapsto \tilde M.$  
 In particular if you have a vector bundle $E$ on $X$, you can recover it (or rather its locally free associated sheaf)  from $M=\Gamma(X,E)$ by this equivalence.   
And this remarkable result is not even very difficult! ( Hartshorne, *Algebraic Geometry*, II Corollary 5.5) . And it is valid on any affine *scheme*! 

**Another interpretation**    
I have interpreted $\mathcal O(E)$ as the vector space $ \Gamma(X,E)$ of global sections of the bundle $E$.    
However Donu Arapura and Qfwfq consider that the notation designates the sheaf of sections of the vector bundle $E$, that is the sheaf $\mathcal E$ associating to the open subset $U\subset X$ the vector space $\mathcal E(U)=\Gamma(U,E)$.    
 I now think that their point of view is the better one!   
In that case the answer is : yes, that sheaf  determines the bundle.      
Indeed there is a *canonical* way to obtain  from the sheaf $\mathcal E=\mathcal O(E)$ a holomorphic vector bundle $ Vec(\mathcal E) $ isomorphic to $E$.     
Its fiber at $x\in X$ is the the $\mathcal O_{X,x}/ \mathfrak m_x=\mathbb C$- vector space  $Vec(\mathcal E) [x]=\mathcal E _x/\mathfrak m_x \mathcal E_x$.    
And the complex structure on $Vec(\mathcal E)=\bigsqcup Vec(\mathcal E) [x]$, is obtained from bijections  with $U\times \mathbb C^r$ for all $U$'s on  which $\mathcal E|U$ is free, that is isomorphic to $\mathcal O^r_U$.   
Of course, there are verifications to be made, which are as straightforward as they are boring and unpleasant  to write down explicitly...